DE202010018205U1 - fridge - Google Patents

Abstract

Refrigerator, comprising: a cabinet (10); a storage room defined inside the cabinet (10), the storage room comprising a refrigerator compartment (102) and a freezer compartment (104); a refrigerator door that opens and closes the storage room, the refrigerator door comprising a refrigerator door (11) and a freezer room door (14); an icebox (120) defined on a door liner (112) defining a rear surface of the refrigerator door (11) and having an icebox door (130); an icemaker (210) disposed in the icebox (120) and configured to produce ice cubes; a drive source (220) providing power to automatically rotate the icemaker (210) to remove the ice cubes from the icemaker (210) by a twisting operation of the icemaker (210); an ice bin (300) provided on the refrigerator door, wherein the ice bin (300) is disposed under the icemaker (210) to receive the ice cubes generated in the icemaker (200); a motor assembly (280) provided on the refrigerator door and connected to the ice container (300); a dispenser (17) disposed in the refrigerator door for dispensing ice; and an ice channel (150) disposed at an underside of the icebox (120) and communicating with an ice mouth (127) formed at the bottom of the icebox (120), the ice bin (300) comprising: a Front wall (311); a back wall (312); Side walls (313); an opening (310) defined on its top surface; a first inclined guide surface (321) inclined downwardly from a wall of the side walls (313) toward its central portion; a second inclined guide surface (322) inclined downwardly from the other wall of the side walls (313) toward its central portion; an ice storage space (315) defined by the front wall (311), the rear wall (313), the side walls (313) and the first and second inclined guide surfaces (321, 322); an iron delivery member (400) disposed between the first inclined guide surface (321) and the second inclined guide surface (322); and a discharge part (500) formed defined between the first inclined guide surface (321) and the second inclined guide surface (322) and having a discharge opening (510), the ice discharge element (400) comprising: an axis of rotation (420) connected to the motor assembly (280) and disposed horizontally in the ice container (300); a plurality of rotary blades (410) fixed to the rotation axis (420) and spaced from each other in an extension direction of the rotation axis (420), each rotation blade (410) having a space (411) for receiving the ice cube; ...

Description

background

The present disclosure relates to a refrigerator.

In general, a refrigerator is a device that stores food using low-temperature air at a low temperature.

The refrigerator includes a cabinet defining a storage room and a refrigerator door that opens and closes the storage room. The storage room may include a cold room and a freezer room. The refrigerator door may include a refrigerator door, the refrigerator compartment, closing, and a freezer compartment door that opens and closes the freezer compartment.

Also, the refrigerator may include an icemaker assembly making ice using cool air to store the produced ice. The icemaker assembly includes an ice maker that produces the ice and an ice container in which the ice deposited by the icemaker is stored. The icemaker may be located inside the refrigerator or in the refrigerator room door. The ice container may be disposed inside the refrigerator or in the refrigerator room door. For user comfort, the refrigerator door may further include a dispenser for dispensing the ice stored in the ice container.

Summary

Embodiments provide a refrigerator with a thin refrigerator door.

Embodiments also provide a refrigerator in which a thickness of a refrigerator door in which an ice container is disposed becomes thin.

In one embodiment, a refrigerator includes: a storage room; a refrigerator door that opens and closes the storage room; an icemaker constructed to produce ice cubes; an ice container provided on the refrigerator door for receiving the ice cube generated in the ice maker and having a discharge opening through which the ice cubes are discharged; a motor provided on the refrigerator door; and at least one sheet within the ice container, wherein the at least one sheet is operatively connected to the engine, wherein at least one ice cube produced in the ice maker falls directly on the at least one sheet and the at least one sheet comprises at least one ice cube formed in the ice the ice container is moved by an operation of the motor to the discharge opening, moves the at least one ice cube from the ice container to the discharge opening to deliver the at least one ice cube from the ice container.

The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features will become apparent from the description and drawings, and from the claims.

Brief description of the drawings

1 is a perspective view of a refrigerator according to a first embodiment.

2 FIG. 10 is a perspective view of the refrigerator according to the first embodiment, wherein a portion of a refrigerator door is opened. FIG.

3 is a perspective view of the refrigerator door according to the first embodiment, wherein a freezer door is opened.

4 is a perspective view of a refrigerator door according to the first embodiment, in which an icemaker assembly is removed from the freezer compartment.

5 and 6 FIG. 15 are perspective views of the ice maker assembly according to the first embodiment. FIG.

7 is a perspective view of an ice container according to the first embodiment.

8th is an exploded perspective view of the ice container.

9 is an exploded perspective view of an Eisabgabeelements.

10 is a front view of a rotary blade of the ice container.

11 Fig. 10 is a front view of the ice delivery member, a fixed blade and an opening / closing member of the ice container.

12 is a perspective view of the opening / closing element of 11 ,

13 is a front view showing the inside of the ice container.

14 is a bottom view of the ice bin.

15 is a top view of the ice bin.

16 FIG. 12 is a vertical sectional view of the refrigerator door of the first embodiment. FIG.

17 is a view of a state in which an icemaker is rotated to remove ice from the icemaker 16 deposit.

18 Fig. 11 is a front view of a state in which ice chips are discharged from the ice bucket.

19 Fig. 11 is a front view of a state in which ice cubes are discharged from the ice container.

20 is a perspective view of a refrigerator according to a second embodiment.

21 is a perspective view of a refrigerator according to a third embodiment.

22 is a perspective view of a refrigerator according to a fourth embodiment.

Detailed description of the embodiments

Reference will now be made in detail to the embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings.

1 is a perspective view of a refrigerator according to a first embodiment. 2 FIG. 10 is a perspective view of the refrigerator according to the first embodiment, wherein a portion of a refrigerator door is opened. FIG.

Referring to 1 and 2 includes a fridge 1 according to this embodiment, a cabinet 10 , which defines its external appearance, and refrigerator doors 11 and 14 Moving with the cabinet 10 are connected.

A storage room for storing food is inside the cabinet 10 Are defined. The storage room includes a refrigerator 102 and a freezer room 104 that under the fridge 102 is arranged.

That is, a refrigerator having a lower freezing portion in which a refrigerating space is disposed above the freezing space will be described as an example in this embodiment.

The refrigerator doors 11 and 14 include a refrigerator door 11 that the refrigerator 102 opens and closes, and a freezer compartment door 14 that the freezer room 104 opens and closes.

The fridge door 11 includes several doors 12 and 13 , which are arranged respectively on left and right sides. The several doors 12 and 13 include a first refrigerator door 12 and a second refrigerator door 13 on the right side of the first refrigerator door 12 is arranged. The first refrigerator door 12 can with respect to the second refrigerator door 13 be independently mobile.

The freezer compartment door 14 includes several doors 15 and 16 which are arranged vertically. The several doors 15 and 16 include a first freezer compartment door 15 and a second freezer door 16 that under the first freezer compartment door 15 is arranged. The first and second freezer doors 12 and 13 can be moved in rotation, and the first and second freezer doors 15 and 16 can be moved by moving.

Alternatively, a freezer compartment door 14 be provided to the freezer compartment 104 to open and close.

A donor 17 for dispensing water or ice is in a door of the first and second refrigerator doors 12 and 13 arranged. For example, the donor is 17 in the first refrigerator door 12 arranged in FIG. Also, an ice maker assembly (to be described later) for producing and storing the ice cubes in a door of the first and second refrigerator doors 12 and 13 arranged.

In this embodiment, the dispenser 17 and the icemaker assembly in the first refrigerator door 12 and the second refrigerator door 13 be arranged. Consequently, it is described below that the dispenser 17 and the icemaker arrangement in the fridge door 11 are arranged. This is the first refrigerator door 12 and the second refrigerator door 13 together as the fridge door 11 designated.

3 is a perspective view of the refrigerator door according to the first embodiment with an open freezer compartment door. 4 is a perspective view of a refrigerator door according to the first embodiment, in which an icemaker assembly is removed from an icebox.

Referring to 1 to 4 includes the cold room door 11 an outer casing 111 and a door lining 112 connected to the outer casing 111 connected is. The door lining 112 defines a rear surface of the refrigerator door 11 ,

The door lining 112 defines an icebox 120 , The icemaker arrangement 200 for generating and storing the ice cubes is arranged inside the icebox. The ice compartment 120 is from an icebox 130 opened and closed. The icebox 130 is by a hinge 139 rotatable with the door lining 112 connected. A handle 140 who is in a state in which the freezer compartment 120 from the freezer door 130 is closed, with the door lining 112 is connected, is on the freezer door 130 arranged.

A grip connection part 128 that with a section of the handle 140 is in the door lining 112 Are defined. The handle connection part 128 takes the section of the handle 140 on.

The cupboard 10 includes a main body supply channel for supplying cooling air to the freezer compartment 120 and a main body return channel 108 to recover the cooling air from the freezer 120 , The main body supply channel 106 and the main body return passage 108 may be associated with a space in which an evaporator (not shown) is located.

The fridge door 11 includes a door supply duct 122 to cooling air of the main body supply channel 106 to deliver to the freezer, and a door return duct 124 to the cooling air of the icebox 120 for the main body return passage 108 to win back.

The door supply channel 122 and the door return channel 124 extend from an exterior wall 113 the door lining 112 to an inner wall 114 holding the ice box 120 forms. The door supply channel 122 and the door return channel 124 are arranged vertically, and the door supply channel 122 is above the door return channel 124 arranged. However, in this embodiment, the positions of the door supply channel 122 and the door return channel 124 not limited to this.

When the fridge door 11 the refrigerator 102 closes, is the door supply channel 122 with the main body supply channel 106 aligned and communicates with it and the door return channel 124 is with the main body return channel 108 aligned and communicates with him.

The ice compartment 120 includes a cooling air duct 290 , the cooling air 290 which are in the door supply duct 122 flows to the icemaker lineup 200 passes. The cooling air duct 290 includes a passage through which cooling air flows, and in the cooling air passage 290 flowing cooling air is finally sent to the icemaker 200 delivered. Because the cooling air through the cooling air duct 290 on the ice maker arrangement 200 can be concentrated, ice cubes can be quickly generated.

The fridge door 11 includes a first connector 125 to the icemaker 200 to supply with a power source. The first connector 125 lies to the ice compartment 120 free. The fridge door 11 includes a water supply line 126 to get water to the icemaker 200 to deliver.

The water supply line 126 is between the outer casing 111 and the door lining 112 arranged, and their end goes through the door lining 112 and is at the freezer 120 arranged.

An ice-opening 127 for dispensing ice cubes is at the bottom of the inner wall 114 the door lining 112 holding the ice box 120 forms, arranged. An ice channel 150 that with the ice opening 127 is at the bottom of the freezer 120 arranged.

Hereinafter, a structure of the ice maker assembly will be described in detail.

5 and 6 FIG. 15 are perspective views of the ice maker assembly according to the first embodiment. FIG.

Referring to 3 to 6 defines the icemaker arrangement 200 Rooms where ice cubes are produced and includes an icemaker 210 holding ice produced, a drive source 220 , the power to automatically rotate the icemaker 210 to ice cubes from the icemaker 210 to remove, provides a gearbox 224 that the power of the drive source 220 on the icemaker 210 transfers, a cover 230 that the icemaker 210 covering to prevent the overflow of water when the water to the icemaker 210 is delivered, and a water supply 240 coming from the water supply line 126 supplied water to the icemaker 210 passes.

The icemaker arrangement 200 includes a holding mechanism 250 with a support part 215 on which the icemaker 210 is arranged, an ice container 300 who left the icemaker 210 removed ice cubes stored, an ice full sensor 270 for sensing the condition of the ice bin 300 in which it is full of ice, and a motor assembly 280 , which selectively with the ice container 300 connected is.

One with the engine assembly 280 connected electric wire and one with the drive source 220 connected electrical wire are connected to a second connector 282 connected removably to the first connector 125 connected is.

In detail, the drive source 220 include an engine.

The holding mechanism 250 includes a first holding part 252 and a second holding part 260 that with the first holding part 252 connected is.

The first holding part 252 is on the ice compartment 120 arranged. The engine arrangement 280 is on the first holding part 252 Installed. An ice-opening 253 through which from the ice container 300 ice cubes being dispensed is in the lower surface of the first holding part 252 arranged. The ice container 300 is on the first holding part 252 arranged. That is, the first holding part 252 holds the ice container 300 ,

When the ice container 300 on the first holding part 252 is arranged, is the motor assembly 280 with the ice container 300 connected. In this embodiment, the state in which the ice container means 300 on the first holding part 252 is arranged, the state in which the icebox 120 the ice container 300 receives.

The support part 215 on which the icemaker 210 is arranged is on the second holding part 260 Installed. The icemaker 210 includes a rotary shaft 212 on one side. The rotary shaft 212 is rotatable with the support part 215 connected. An extension part (not shown) extending from the gearbox 224 extends, is with another side of the icemaker 210 connected.

The ice-full sensor 270 is on the second holding part 260 installed at a position by the icemaker 210 is spaced. The ice-full sensor 270 is under the icemaker 210 arranged.

The ice-full sensor 270 includes a transmission part 271 that sends a signal, and a receiving part 272 that of the transmitting part 271 is spaced and a signal from the transmitting part 271 receives. The transmission part 271 and the reception part 272 are in the interior of the ice bin 300 arranged when the ice container 300 on the first holding part 252 is arranged.

Here below is the ice container 300 described in detail.

7 is a perspective view of an ice container according to the first embodiment.

Referring to 7 is an opening 310 on a top of the ice bin 300 Are defined. The ice container 310 has a front wall 311 , a back wall 312 and sidewalls 313 ,

An inclined guide surface is inside the ice container 300 arranged to hold the stored ice cubes and direct the stored ice cubes so that the ice cubes slide down by their own weight.

An ice storage room 315 , in which the ice cubes are stored, is through the front wall 311 , the back wall 312 , the side walls 313 and the inclined guide surface 320 Are defined.

The inclined guide surface 320 includes a first inclined guide surface 321 and a second inclined guide surface 322 , The first inclined guide surface 321 is from a wall of sidewalls 313 inclined downwards in the direction of a middle section. The second inclined guide surface 322 is from the other wall of the sidewalls 313 inclined in the direction of the middle section.

An ice delivery element 400 is between the first inclined guide surface 321 and the second inclined guide surface 322 arranged around the in the ice cube container 300 taken ice cubes outside of the ice container 300 leave. That is, the first inclined guide surface 321 and the second inclined guide surface 322 are on the left and right sides of the Eisabgabeelements 400 arranged.

The Eisabgabeelement 400 comprises at least one rotary blade 410 to a given space 411 to define in which the ice cubes are arranged. The Eisabgabeelement 400 can have several rotation sheets 410 to release the ice cubes easily.

Hereinafter, the iron discharging element becomes 400 with the several rotary leaves 400 as an example.

The on the first inclined guide surface 321 and the second inclined guide surface 322 arranged ice cubes are by their own weight in the direction of the Eisabgabeelements 40 emotional. Then the ice cubes become through an operation of the Eisabgabeelements 400 delivered to the outside.

The Eisabgabeelement 400 is rotatable between the first inclined guide surface 321 and the second inclined guide surface 322 arranged. There is also a donation part 500 with a discharge opening 510 in which the ice cubes are finally discharged between the first inclined guide surface 321 and the second inclined guide surface 322 arranged.

The Eisabgabeelement 400 is rotatable forward / backward (or rotatable in both directions) on the dispensing part 500 arranged.

When the iron delivery element 400 is rotated in a first direction is at least one solid sheet 480 that with the rotary pages 410 interacts to smash the ice cubes on one side of a lower portion of the ice delivery element 400 ie one side of the delivery part 500 arranged.

To smash the ice cubes easily, can use several solid leaves 480 in the ice container 300 be arranged. Here below is the ice container 300 with the several solid leaves 480 as an example.

The several solid leaves 480 are spaced from each other, and the rotary blades 410 go through a space between the several solid leaves 480 ,

If the ice through the rotation operations of the rotary blades 410 in a state where the ice between the solid leaves 480 and the rotary blades 410 is pinched, the ice is shattered to form ice chips.

When the iron delivery element 400 is rotated in a second direction opposite to the first direction, becomes an opening / closing member 600 that selectively with the discharge opening 510 and the ice storage room 315 communicating to deliver ice cubes on the side of the lower portion of the ice delivery element 400 ie the side of the delivery part 500 arranged.

An operating limitation part 650 is under the opening / closing element 600 arranged to an operating range of the opening / closing element 600 to thereby prevent overly ice cubes from being dispensed.

The delivery part 500 has a delivery guide wall 520 with a structure of a rotation path of the rotary blade 410 equivalent. The solid leaves 480 are under the delivery guide wall 520 arranged.

The delivery guide wall 520 prevents the smashed ice chips on the delivery part 500 remain. An anticyclone prevention part 330 pointing in the direction of the rotary blade 410 protrudes, is on a back surface 312 the front wall 311 of the ice container 300 arranged to prevent ice cubes between the rotary blades 410 and the front wall 311 of the ice container 300 be trapped.

8th is an exploded perspective view of the ice container.

Referring to 7 and 8th are several rotation sheets 410 on a rotation axis 420 attached. The rotation axis 420 goes through a connection plate 428 that with a retaining plate 425 and the engine assembly (see reference number 280 from 6 ) connected is. The rotation axis 420 is inside the ice bin 300 arranged horizontally.

The several rotation sheets 410 are in a direction parallel to an extension direction of the rotation axis 420 spaced apart from each other.

The rotation axis 420 is with one side of each of the several solid leaves 480 connected. That is, the axis of rotation 420 goes through the several solid leaves 480 , A through hole 481 through which the axis of rotation 420 is, is in the respective solid sheets 480 Are defined.

Here is the through hole 481 have a diameter larger than that of the axis of rotation 420 is, so that the solid leaves 480 not be moved when the axis of rotation 420 is rotated.

The several rotation sheets 410 and the several solid leaves 480 can be in the direction parallel to the extension direction of the rotation axis 420 be arranged alternately.

As described above, the other side is each of the plurality of solid sheets 480 on an underside of the delivery guide wall 520 attached. A fastener 485 is with the other side of the respective solid leaves 480 connected and in a groove 521 used in the delivery guide wall 520 is defined.

The opening / closing element 600 can be provided simply or repeatedly. The opening / closing element 600 is on a lateral side of the several solid leaves 480 arranged.

The opening / closing element 600 is rotatable on the dispensing part 500 arranged. The opening / closing element 600 may be formed of an elastic material or of an elastic element 640 , such as a spring, are held.

This is done to the opening / closing element 600 to bring back into its initial position when in a state in which one end of the opening / closing element 600 is moved downward by the compression effect due to the ice cube, a compression effect is released.

The Eisabgabeelement 400 , the solid sheet 480 and the opening / closing element 600 are inside the ice container 300 arranged and then becomes a front panel 311 which the front wall 311 of the ice container 300 forms, arranged.

A cover element 318 may be at a lower portion of a front surface of the front panel 311 be arranged to prevent the opening / closing element 600 or the solid sheet 480 to the outside.

9 is an exploded perspective view of an Eisabgabeelements.

Referring to 7 to 9 is an elastic element 429 with a spiral shape between the holding plate 425 and the connection plate 428 arranged to the connection plate 428 to keep elastic.

In a state where the rotary blade 410 , the retaining plate 425 , the connection plate 428 and the elastic element 429 with the rotation axis 420 are connected, becomes an insert element 421 in a front end of the axis of rotation 420 used.

The engine assembly (see reference number 280 from 6 ) comprises a connecting element 320 , which selectively with the connection plate 428 is connected. A lead 430 on which the connecting element 320 is hooked on the connection plate 428 arranged.

If the lead 430 and both ends of the connecting element 320 in a state in which a user the ice container 300 in the freezer 120 receives, are aligned with each other, is the connecting element 320 not on the lead 430 hooked. In this case, the guide plate 428 through the elastic element 429 in the direction of the holding plate 425 emotional.

After that, the alignment between both ends of the connecting element 320 and the lead 430 by continued operation of the engine assembly (see reference number 280 from 6 ) is dissolved, the connection plate 428 through the elastic element 429 moved backwards, and thus both ends of the connecting element 320 on the lead 430 hooked.

The holding plate 425 has a sloped surface 426 to put on a side surface of the retaining plate 425 arranged ice cubes smoothly towards the multiple rotation leaves 410 to move.

10 is a front view of a rotary blade of the ice container.

Referring to 10 include the respective rotary blades 410 a middle section 412 through which the axis of rotation 420 goes, and extension parts 413 extending radially from the middle section 412 extend.

A through hole 415 through which the axis of rotation 420 is, is in the middle section 412 Are defined. The through hole may have a non-circular shape or a long hole shape by a rotational force of the rotation axis 420 smoothly on the middle section 412 transferred to.

The several extension parts 413 can be spaced apart from each other. A room 411 , in which the ice cubes are arranged, is between the two adjacent extension parts 413 Are defined.

The respective extension parts 413 have a width gradually from the middle part 412 increases to the outside. A hook part 416 is on one end of the extension 413 arranged to prevent those in the room 411 overflowing arranged ice cubes.

Consequently, if the rotary blade 410 in a state where the ice cubes in the room 411 To be taken up, the ice cubes are attached to the end of the extension section 413 are arranged, hooked and together with the rotary blade 410 in a direction of rotation of the rotary blade 410 emotional.

A fragmentary part with a sawtooth shape is on one side of the extension part 413 arranged to the ice by interacting with the solid sheet 480 to smash.

A smooth surface is on the other side of the extension 413 arranged to the ice cubes to a side opposite to the fragmentation part 418 while the ice cubes are preserved in the ice cube state. Consequently, the fragmentation part is 418 an extension part 418 on one side opposite to the smooth surface of the other extension part 418 in a room 411 arranged.

11 Fig. 10 is a front view of the ice delivery member, a fixed blade and an opening / closing member of the ice container.

If the rotary blade 410 Referring to 11 with the rotation axis 420 is connected, overlap the multiple rotation sheets 410 not complete, but are arranged from a front side toward a rear side in a slightly twisted state.

That is, as seen from a front side, the plurality of rotary blades overlap 410 not completely, but are arranged in a state in which the rear rotary blade 410 is rotated by a predetermined angle.

If the multiple rotation sheets 410 are arranged in front and back directions in a fully overlapping relationship, a pressure applied to the ice cubes is distributed when the plurality of rotary blades 410 to smash the ice cubes in the first direction. As a result, it is difficult to smash the ice cubes.

However, as described above, in the case where the plural rotation blades are successively arranged in a state of being rotated at a predetermined angle, the ice cubes contact the fragmentation part 418 of the first rotary sheet 410 and are thus smashed. Thereafter, the shattered ice cubes successively contact the fragmentation part 418 of the second rotary sheet 410 and then with a predetermined time interval the fragmentation part 418 of the third rotary blade 410 ,

Consequently, the rotational force of the Eisabgabeelements 400 to the respective fragmentation parts 418 be concentrated to significantly improve the Eiszertrümmerungswirkungsgrad.

Also, the fragmentation part 488 with the sawtooth shape on the solid sheet 480 be arranged to smash the ice cubes.

The opening / closing element 600 is in a lateral direction of the solid sheet 480 arranged. The opening / closing element 600 comprises a rotating part 605 the rotatable within the ice container 300 is arranged. The rotation part 605 is from the elastic element 640 held elastically with a torsion spring shape. The elastic element 640 has an end to the ice container 300 attached and the other end on a surface of the opening / closing member 600 sit around the opening / closing element 600 to keep elastic.

The opening / closing element 600 has a rounded first guide surface 610 and a second guide surface 612 that with the rotation part 605 connected is. At this time form the second guide surface 612 and the second inclined guide surface (see reference number 322 from 7 ) a coherent surface.

12 is a perspective view of the opening / closing element 600 from 11 ,

Referring to 6 and 12 can the opening / closing element 600 be provided multiple times. The multiple opening / closing elements 600 are moved independently with respect to each other.

If a single opening / closing element 600 in the ice container 300 can be arranged through a gap where the ice is not arranged, if the ice cubes are not discharged, but only longer on a section of the first guide surface 610 of the opening / closing element 600 stay, other ice cubes are dispensed.

If, however, several opening / closing elements 600 are arranged in the ice container, even if the ice cubes on an opening / closing element 600 are hooked to the opening / closing element 600 in an open state, the other opening / closing element 600 on which the ice cubes are not hooked, maintain a closed state to prevent the ice cubes from being unnecessarily discharged.

At this time, the elastic member may be on each of the plurality of opening / closing members 600 be arranged. The respective opening / closing elements 600 include a hook jaw 615 to prevent that between the opening / closing elements 600 and the several rotary blades 410 jammed ice cubes are discharged to the outside when each of the opening / closing elements 600 in the closed state.

The hook jaw 615 may be on one end of an upper surface of the first guide surface 610 be arranged.

13 is a front view showing the inside of the ice container, and 14 is a bottom view of the ice bin.

Referring to 6 to 14 is the first inclined guide surface 321 adjacent to the plurality of solid sheets 480 arranged. The second inclined guide surface 322 is adjacent to the opening / closing element 600 arranged.

A delivery guide wall 520 that with the first inclined guide surface 321 is on one side of the delivery part 500 arranged. The second inclined guide surface is divided into two sections. This is done to a speed of movement along the second inclined guide surface 322 in the direction of the Eisabgabeelements 400 Adjust moving ice cubes to prevent the ice cubes from breaking out.

The second inclined guide surface 322 includes an outwardly inclined guide surface 322b that with the side walls 313 of the ice container 300 is connected, and an inwardly inclined guide surface 322a with the outward inclined guide surface 322b is connected and adjacent to the Eisabgabeelement 400 is arranged.

The inwardly inclined guide surface 322a is inclined at an angle smaller than that of the outwardly inclined guide surface 322b is. Consequently, the speed of the ice cubes along the outward inclined guide surface 322b downwards on the inwardly inclined guide surface 322a reduced. The second guide surface 612 of the opening / closing element 600 is at one end of the inwardly inclined guide surface 322a arranged so that they together with the inwardly inclined guide surface 322a forms a coherent surface.

When the opening / closing element 600 the discharge opening 510 closes form the second guide surface 612 and the inwardly inclined guide surface 322a the contiguous surface to reduce the speed of movement of the ice cubes.

When the opening / closing element 600 the discharge opening 510 opens, becomes the second guide surface 612 moves downwards to the ice cubes towards the discharge opening 510 to move. A tilt endpoint 321a the first inclined guide surface 321 is at a higher position than the axis of rotation 420 the Eisabgabeelements 400 arranged. This is done to prevent fragments of the ice cubes smashed at a position on which the solid sheet 480 is arranged to be moved up again.

To prevent the fragments of the shattered ice cubes from dwelling, the delivery guide wall can 520 have a curvature that of the rotation path of the rotary blade 410 equivalent.

In order to keep the ice cubes also in the ice cube state, the second inclined guide surface may 322 inclined at an angle smaller than that of the first inclined guide surface 321 is.

The inwardly inclined guide surface 322a the second inclined guide surface 322 may be at substantially the same angle as that of the second guide surface 612 of the opening / closing element 600 be inclined to form a continuous surface.

The rotation part 605 of the opening / closing element 600 is located at a position lower than that of the rotation axis 420 the Eisabgabeelements 400 is, leaving the second inclined guide surface 322 inclined at an angle smaller than that of the first inclined guide surface 321 is.

The operating limitation part 650 for limiting an opening angle of the opening / closing element 600 is under the opening / closing element 600 arranged.

The operating limitation part 650 includes a vertically arranged first rib 651 , one of the first rib 651 spaced second rib 652 with a higher height than the first rib 651 and a sloped contact part 653 , which is an upper section of the first rib 651 with an upper portion of the second rib 652 combines.

The opening / closing element 600 is by contacting the contact part 653 stopped.

As described above, the opening / closing member 600 be provided multiple times. Also, the opening / closing elements 600 have maximum opening angles that differ from each other.

15 is a top view of the ice bin.

Referring to 15 is the anticyclone prevention part 330 inside the front wall 311 of the ice container 300 arranged. The anticyclone prevention part 330 stands from the front wall 311 of the ice container 300 in front or extends inwards.

The anticyclone prevention part 330 is in a space between the rotary blade 410 , which is on the front side of the several rotary blades 410 is arranged, and the front wall 311 arranged.

The anticyclone prevention part 330 may be disposed over a portion where the shattered ice cubes are delivered.

16 FIG. 12 is a vertical sectional view of the refrigerator door of the first embodiment and FIG 17 is a view of a state in which an icemaker is turned to ice from the icemaker 16 deposit.

Referring to 16 and 17 is the ice container 300 in a state in which the icemaker arrangement 200 in the freezer 120 is arranged, substantially vertically below the icemaker 210 arranged.

In detail is an inlet 301 the opening 310 of the ice container 300 placed at a position lower than that of the icemaker 210 is. If therefore the freezer door 130 the ice box 120 closes, is the ice container 300 not in a first area A between the freezer door 300 and the icemaker 210 arranged. That is, the ice container 300 in a second area, except for a first area between the freezer door 130 and the icemaker 210 , in an entire area of the freezer 120 can be arranged.

This is done for a reason that the ice container 300 the ice container 300 does not need to arrange in the first area A, since the icemaker 210 is reversed by its rotation operation to ice cube I due to the dead weight of the ice cubes from the icemaker 210 to deposit, bringing them into the ice container 300 fall. That is, because of the icemaker 210 deposited ice cubes I need not go through the first area A, the ice container need not be placed in the first area A.

As the ice container 300 not located in the first area A, the freezer door can 130 thus further adjacent to the icemaker 210 be arranged. As a result, a total thickness of the refrigerator door 11 be reduced. That is, the refrigerator door 11 can be thin.

The rotary shaft 212 of the icemaker 210 cuts the axis of rotation 420 inside the ice container 300 is arranged. This is done as the volume of the icebox 120 increases when the rotary shaft 212 of the icemaker 210 parallel to the axis of rotation 420 is arranged inside the ice container 300 is arranged.

The several rotation sheets 410 may be in a direction parallel to the direction of extension of the axis of rotation 420 be spaced apart from each other. The several rotation sheets 410 may be within a range of a front-rear width W of the icemaker 210 be arranged.

If thus the icemaker 210 is rotated to the ice cubes I from the icemaker 210 To part, part of the several ice cubes falling from the icemaker falls 210 deposited directly into at least one rotary blade of the multiple rotary blades 410 , That is, that of the icemaker 210 deposited ice cubes I fall by their own weight, and at least one of the falling ice cubes I contacts at least one rotary blade 410 directly.

At this time, the fall direction intersects that of the icemaker 210 deposited ice cubes I the expansion direction of the rotation axis 420 , In another aspect, the direction of fall is that of the icemaker 210 deposited ice cubes I substantially parallel to a virtual surface, which is defined when the multiple rotation leaves 410 be rotated.

A horizontal distance from the freezer compartment door 130 to the rotary shaft 212 of the icemaker 210 is greater than the shortest horizontal distance from the freezer door 130 to the discharge opening 510 ,

Hereinafter, a moving method of ice cubes produced at the ice maker assembly will be described.

18 is a front view of a state in which ice chips are discharged from the egg container, and 19 Fig. 11 is a front view of a state in which ice cubes are discharged from the ice container.

A method of discharging the generated ice cubes outward will be described with reference to FIG 16 to 18 described.

To get the ice cubes from the icemaker 210 to separate, becomes the power source 220 operated when an operating signal in the drive source 220 is entered. A power of the drive source 220 is from the gearbox 224 on the icemaker 210 transferred to the icemaker 210 to rotate in total.

In this embodiment, the ice cubes are formed by the twisting operation of the ice maker 210 deposited. When the twisting operation of the icemaker 210 One end and the other end of the icemaker will be performed 210 twisted by their relative movement. Consequently, the ice cubes from the ice maker 210 deposited. As a principle of the twisting operation of the icemaker 210 is well known, detailed descriptions are omitted.

The one by the icemaker 210 deposited ice cubes fall through the inlet 301 the opening 310 of the ice container 300 in the ice container 300 ,

As described above, part of the ice maker 210 deposited ice cubes on the several rotation leaves 410 fall, another part of the ice cube may be on the first inclined guide surface 321 fall and yet another part of the ice cube may be on the second inclined guide surface 322 fall.

To deliver the smashed pieces of ice, comes the fragment of destruction 418 the multiple rotation sheets 410 close to the fragmentation part 488 of the solid sheet 480 if the iron delivery element 400 in the first direction (in 18 seen in a counterclockwise direction) is rotated.

Consequently, those in the room 411 the multiple rotation sheets 410 arranged ice cubes by the rotation of the rotary blades 410 on the solid sheet 480 arranged. In this embodiment, those in the room 411 arranged ice cubes the ice cubes, directly on the several rotation leaves 410 fall, or the ice cubes, along the first inclined guide surface 321 slide, be.

If in this state the multiple rotation sheets 410 are continuously rotated in the first direction, which are between the fragmentation part 418 of the rotary blade 410 and the smash part 488 of the solid sheet 480 crushed ice cubes smashed. The shattered ice chips fall in a direction of the discharge opening 510 and are delivered to the outside.

In a method of discharging the ice chips, the opening / closing member 600 held in the closed state, it can prevent the on the second inclined guide surface 322 arranged ice cubes are delivered.

If, in a method for dispensing the ice cubes, the ice dispensing element 400 in the second direction (in 18 when viewed in a clockwise direction), those in the room are rotated 411 the multiple rotation sheets 410 arranged ice cubes by the rotation of the rotary blades 410 in a direction of the opening / closing member 600 emotional.

The one in the room 411 the multiple rotation sheets 410 arranged ice cubes may be the ice cubes directly on the several rotation leaves 410 fall, or the ice cubes, along the second inclined guide surface 322 slide, be.

If the multiple rotation sheets 410 are continuously rotated in the second direction, pushes the extension part 413 the respective rotation sheets 410 that on the opening / closing element 600 arranged ice cubes. As a result, the compression forces of the rotary blades become 410 through the ice cubes on the opening / closing element 600 applied.

As a result, the opening / closing member becomes 600 by the compression force of the ice cubes and the rotary blades 410 downwards (in 19 seen in a counterclockwise direction). As a result, between one end of the extension part 413 the respective rotation sheets 410 and one end of the opening / closing member 600 defines a room. Then the ice cubes are moved into the room and finally the ice cubes are released to the outside.

When the rotation of the Eisabgabeelements 400 is stopped, the opening / closing element returns 600 by the elastic force of the elastic element 640 back to its initial position because of the opening / closing element 600 applied pressure is removed.

A summary of the movement of ice cubes inside the ice bin 300 is as follows. The ice cubes resting on the several rotation leaves 410 fall, are moved down when the multiple rotation leaves 410 be rotated.

The ice cubes resting on the first inclined guide surface 321 fall, by their own weight in the room 411 moves when the multiple rotation sheets 410 be rotated in the first direction. If the multiple rotation sheets 410 be rotated, the ice cubes are inside the room 411 moved downwards.

Also, the on the second inclined guide surface 322 falling ice cubes by their own weight in the room 411 moves when the multiple rotation sheets 410 be rotated in the second direction. If the multiple rotation sheets 410 be rotated, the ice cubes are inside the room 411 moved downwards.

In essence, those on the respective inclined surfaces 321 and 322 arranged ice cubes in a state in which the operation of the multiple rotation leaves 410 stopped, not moved.

As a result, the stored ice cubes according to this embodiment can be formed by the rotational operation of the plurality of rotating blades 410 be discharged to the outside, without that an additional transfer unit within the ice container 300 is required.

Also, the ice cubes are inside the ice container 300 apart from the reciprocal movement between the ice cubes, only from the top to the bottom, ie the inlet 301 of the ice container 300 to the discharge opening 510 , emotional.

If the inlet 301 of the ice container 300 and the discharge opening 510 of the ice container 300 , the ice opening 253 of the first holding part 252 , the opening of the door lining 112 , an inlet 152 and outlet 154 of the ice channel overlap each other, a common overlap area is formed. Consequently, the travel of the ice cubes can be minimized.

A technical meaning of this embodiment according to the above-described construction will be described below.

As described above, since the ice cubes are moved from the upper side to the lower side within the ice container and are moved and dropped by the plural rotating blades, the thickness of the ice container can be reduced.

In this embodiment, the thickness of the ice container represents a thickness of the ice container in the direction of extension of the axis of rotation.

The thickness of the refrigerator door can be reduced by reducing the thickness of the ice container and the position of the ice container within the freezer compartment according to the method of depositing the ice cubes from the icemaker.

When the thickness of the refrigerator door is reduced, a basket may be disposed for additionally accommodating the food in the refrigerator door.

In addition, when the thickness of the refrigerator door is reduced, the capacity of the cooling space can increase since the volume of a portion (which is inserted into the refrigerator) of the refrigerator door is reduced.

20 is a perspective view of a refrigerator according to a second embodiment.

This embodiment is the same as the first embodiment except for one kind of the refrigerator and a position of an ice maker. Thus, only specific portions of this embodiment will now be described.

Referring to 20 can a fridge 70 According to this embodiment, be a side-by-side refrigerator in which a refrigerator 712 and a freezer room 714 are each arranged on the left and right sides.

The freezer room 712 is through a freezer compartment door 720 opened and closed, and the refrigerator 714 is through a fridge door 730 opened and closed.

The refrigerator 70 includes an icemaker assembly 740 for producing ice cubes.

The icemaker arrangement 740 includes an icemaker 750 for producing the ice cubes and an ice container 760 for storing the ice-cream maker 750 deposited ice cubes.

In this embodiment, apart from positions of the ice maker and the ice container, the ice maker assembly has the same structure as that of the first embodiment.

The icemaker 750 is in the freezer room 712 arranged, and the ice container 760 is separable in the freezer compartment door 720 arranged. When the freezer door 720 the freezer room 712 closes, is the ice bin 760 under the icemaker 750 arranged.

According to this embodiment, the thickness of the freezer compartment door can be reduced due to the improved structure of the ice container.

21 is a perspective view of a refrigerator according to a third embodiment.

This embodiment is the same as the second embodiment except for a position of an ice maker assembly. Thus, only specific portions of this embodiment will now be described.

Referring to 21 includes a freezer compartment door 770 This embodiment, a door lining 772 , which is an icebox 774 Are defined. The ice compartment 774 includes an icemaker assembly 780 , In this embodiment, the icemaker assembly 780 the same structure as that of the first embodiment. According to this embodiment, the thickness of the freezer door can be reduced due to the operation of the ice maker and the improved structure of the ice container described in the first embodiment.

22 is a perspective view of a refrigerator according to a fourth embodiment.

This embodiment is the same as the first embodiment except for a position of an ice maker assembly. Thus, only specific portions of this embodiment will now be described.

Referring to 22 For example, a refrigerator with lower freezer compartment will be described as an example. An ice container 860 is in one of the refrigerator doors 820 and 830 arranged. Other components (eg an icemaker 850 ) of an icemaker assembly, except for the ice container 860 , are in the freezer room 812 arranged.

A first insulating housing 870 for isolating a room in which ice cubes are generated from the refrigerator 812 is in the fridge 812 arranged. The icemaker 850 is inside the first insulating housing 870 arranged. A lower surface of the first insulating housing 870 can be opened, and thus can in the icemaker 850 ice cubes are falling down.

Also is a second insulating housing 880 for picking up the ice container 860 arranged in the refrigerator door. An upper surface of the second insulating housing 880 Can be opened to pick up the ice cubes. When the refrigerator door closes the refrigerator, the second insulating housing is disposed below the first insulating housing.

At this time, a seal member (not shown) may be provided on one of the first and second insulating housings 870 and 880 be arranged to a space between a lower surface of the first insulating housing 870 and an upper surface of the second insulating housing 880 seal.

According to this embodiment, the thickness of the refrigerator door can be reduced due to the improved structure of the ice container.

According to the proposed embodiments, since the ice cubes inside the ice container are moved from top to bottom and moved and dropped by the plurality of rotating blades, the thickness of the ice container can be reduced.

Also, the thickness of the refrigerator door can be reduced by reducing the thickness of the ice container and the position of the ice container within the freezer compartment according to the method of depositing the ice cubes from the icemaker.

When the refrigerator door becomes thin, a basket may be disposed in the refrigerator door for additionally containing the food.

Also, when the refrigerator door becomes thin, since the volume of a portion (which is put in the storage space) of the refrigerator door is reduced, the storage capacity of the storage space may increase.

While embodiments have been described above with reference to some illustrative embodiments, it will be understood that numerous other modifications and embodiments may be contemplated by those skilled in the art that fall within the scope of the principles of the disclosure. In particular, various variations and modifications of components and / or arrangements of the combination assemblies are included within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications of the components and / or arrangements, alternative uses will be apparent to those skilled in the art.

Claims (10)

Refrigerator, which has: a closet ( 10 ); a storage room inside the closet ( 10 ), wherein the storage space is a cold room ( 102 ) and a freezer compartment ( 104 ); a refrigerator door that opens and closes the storage room, the refrigerator door opening a refrigerator door ( 11 ) and a freezer compartment door ( 14 ); an icebox ( 120 ) on a door lining ( 112 ), which defines a rear surface of the cold room door ( 11 ) and an icebox ( 130 ) Has; an icemaker ( 210 ) in the freezer compartment ( 120 ) and constructed to produce ice cubes; a drive source ( 220 ) that provides power to the icemaker ( 210 ) to automatically rotate the ice cubes out of the icemaker ( 210 ) by a twisting operation of the ice maker ( 210 ) to remove; an ice container ( 300 ), which is provided on the refrigerator door, wherein the ice container ( 300 ) under the ice maker ( 210 ) is arranged around the in the ice maker ( 200 ) to absorb ice cubes produced; a motor assembly ( 280 ) provided on the refrigerator door and with the ice container ( 300 ) connected is; a donor ( 17 ) disposed in the refrigerator door to deliver ice; and an ice channel ( 150 ) located at the bottom of the freezer compartment ( 120 ) and with an ice opening ( 127 ) at the bottom of the freezer compartment ( 120 ), wherein the ice container ( 300 ) has: a front wall ( 311 ); a back wall ( 312 ); Side walls ( 313 ); an opening ( 310 ) defined on its top; a first inclined guide surface ( 321 ) from a wall of the side walls ( 313 ) is inclined downwards in the direction of its middle section; a second inclined guide surface ( 322 ) from the other wall of the side walls ( 313 ) is inclined downwards in the direction of its middle section; an ice storage room ( 315 ) passing through the front wall ( 311 ), the back wall ( 313 ), the side walls ( 313 ) and the first and second inclined guide surfaces ( 321 . 322 ) is defined; an ice delivery element ( 400 ) located between the first inclined guide surface ( 321 ) and the second inclined guide surface ( 322 ) is arranged; and a dispensing part ( 500 ) located between the first inclined guide surface ( 321 ) and the second inclined guide surface ( 322 ) is defined and a discharge opening ( 510 ), the ice delivery element ( 400 ) comprises: a rotation axis ( 420 ) connected to the engine assembly ( 280 ) and horizontally in the ice container ( 300 ) is arranged; several rotary blades ( 410 ), which at the rotation axis ( 420 ) are fixed and spaced from each other in an extension direction of the axis of rotation ( 420 ) are arranged, each rotation sheet ( 410 ) a room ( 411 ) to pick up the ice cube; several solid leaves ( 480 ) which are constructed to rotate alternately with the plurality of rotary blades ( 410 ) in the direction of expansion of the axis of rotation ( 420 ), at least one in the icemaker ( 210 ) produced ice cube directly on the at least one of the plurality of rotary blades ( 420 ), where when the rotary blades ( 410 ), the ice cubes in the ice storage room ( 315 ) in the room ( 411 ), together with the rotary blades ( 410 ) in a direction of rotation of the rotary blades ( 410 ) and move through the delivery part ( 500 ) to the delivery opening ( 510 ), characterized in that the dispensing part ( 500 ) a delivery guide wall ( 520 ) extending from a slope endpoint ( 321a ) of the first inclined guide surface ( 321 ) and having a structure corresponding to a rotational path of the rotary blade ( 410 ), the slope endpoint ( 321a ) of the first inclined guide surface ( 321 ) in a higher position than the axis of rotation of the Eisabgabeelements ( 400 ) is arranged. Refrigerator according to claim 1, wherein the plurality of rotary blades ( 410 ) are arranged so that they in the direction of extension of the axis of rotation ( 420 ) partially overlap by being shifted by a predetermined angle. Refrigerator according to claim 1 or 2, wherein each of said plurality of rotary blades ( 410 ) comprises: a middle section ( 412 ), through which the axis of rotation ( 420 ) goes; several extension parts ( 413 ) extending radially from the central portion (FIG. 412 ) and are spaced apart from each other, wherein each of the plurality of extension parts ( 413 ) has a width extending from the middle section ( 412 ) gradually increases towards its outer end. Refrigerator according to claim 3, wherein each of said plurality of extension parts ( 413 ) comprises: a first side surface constructed to push the ice cubes when the rotating blade ( 410 ) is rotated in a first direction; and a second side surface configured to face the first side surface to push the ice when the rotation blade (14) is rotated. 410 ) is rotated in the second direction; one or more pieces of fragmentation ( 418 protruding from the first side surface in the direction of the first direction to smash the ice cubes; and a hook part ( 416 ) formed to protrude at an end of the second side surface in the direction of the second direction, the second side surface being concavely curved to make the space (FIG. 411 ) to keep the ice cubes smooth when the rotary blade ( 410 ) is rotated in the second direction. Refrigerator according to claim 1, wherein one side of each of the plurality of solid sheets ( 480 ) with the axis of rotation ( 420 ), and the other side of the plurality of solid sheets ( 480 ) on an underside of the delivery guide wall ( 520 ) is attached. Refrigerator according to claim 1, wherein an inlet ( 301 ) of the ice container ( 300 ), the delivery element ( 400 ) between the first and second inclined guide surfaces ( 321 . 322 ), the discharge opening ( 510 ) of the delivery part ( 500 ), the opening ( 127 ) of the freezer ( 120 ) and an inlet ( 152 ) of the ice channel ( 150 ) are constructed such that they at least partially overlap each other to form an overlapping common area. Refrigerator according to claim 1, wherein the second inclined guide surface ( 322 ) is inclined at an angle which is smaller than that of the first inclined guide surface ( 321 ). Refrigerator according to claim 7, wherein the second inclined guide surface ( 322 ) comprises: an outwardly inclined guide surface ( 322b ) extending from one of the side walls ( 313 ) of the ice container ( 300 ) extends; and an inwardly inclined guide surface ( 322a ) extending from a lower end of the outwardly inclined guide surface ( 322b ), wherein the inwardly inclined guide surface ( 322a ) is inclined at an angle which is smaller than an angle of the outwardly inclined guide surface ( 322b ). Refrigerator according to claim 8, further comprising an opening / closing element ( 600 ) which is rotatable in the dispensing part ( 500 ), wherein the opening / closing element ( 600 ) comprises: a first guide surface ( 610 ), which is rounded off; and a second guide surface ( 612 ) extending from an upper end of the first guide surface ( 610 ), wherein the second guide surface ( 612 ) at the same angle of the inwardly inclined guide surface ( 322a ) is inclined to form a continuous surface. Refrigerator according to claim 8, further comprising an operation limiting part ( 650 ), which under the opening / closing element ( 600 ) is arranged to define an operating range of the opening / closing Closing element ( 600 ), which prevents the ice cubes from being excessively discharged.

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