TR201903481T4 - A refrigerator. - Google Patents

Abstract

The invention includes a cabinet (10) having a storage compartment; a refrigerator door (11) that opens and closes the storage compartment; an ice maker (210) defining an area for forming ice; an ice box (300) mounted on the refrigerator door and placed under the ice maker (210) to receive the ice formed in the ice maker (210); a drain hole (510) in the bottom of this ice box (300); a motor assembly (280) provided in the refrigerator door (11) and including a connection element (281); an ice removal member (400) disposed in the ice box (300) for selectively removing ice from the ice box (300) and comprising; an axis of rotation (420) positioned horizontally within the ice box (300); a group of rotary blades (410) fixed to the rotation axis (420) and spaced apart from one another in a longitudinal direction of the rotation axis (420); A set of fixed blades (480) arranged alternately with the group of rotary blades (410) in the longitudinal direction of the rotation axis (420), the de-icing member further includes: a link plate (428) selectively attached to the fastener (281); a protrusion (430) formed in the connection plate (428) for attachment to the fastener (281); a support plate (425); the rotation axis (420) passes through the link plate (428) and the support plate (425); The discharge member 400 further includes a resilient member 429 placed between the support plate 425 and the link plate 428 to flexibly support the link plate 428, and the support plate 425 includes rotating blades of ice falling from the icemaker It relates to a refrigerator comprising an inclined surface 426 to be moved towards the group 410.

Description

DESCRIPTION REFRIGERATOR Background of the Invention This description is about a refrigerator.

In general, a refrigerator is a refrigerator that uses low temperature air to store food at a low temperature. is a tool.

The refrigerator is designed to open and close a cabinet and storage compartment, in which a storage compartment is defined. Includes a refrigerator door to close. storage compartment, a refrigerator compartment and a May contain freezer compartment. The refrigerator door is a key for opening and closing the refrigerator compartment. refrigerator compartment door and a freezer for opening and closing the freezer compartment may contain a compartment door.

At the same time, the refrigerator is an ice maker to store ice made using cold air. may also include the device. The ice maker consists of an ice maker and an ice maker. Contains an ice box where the separated ice is stored. The ice maker is in the refrigerator compartment or can be found on the refrigerator compartment door. The ice box is in the refrigerator compartment or in the refrigerator. can be found on the compartment door. For the convenience of users, the refrigerator compartment door is also It may also include an icebox for dispensing the ice stored in the ice box. The related technology is also shown in the documents.

Summary of the Invention Concrete examples are a refrigerator door with an ice box in it becoming thinner. refrigerator is provided.

The invention is set forth in the claims.

Details of one or more embodiments are set forth in the accompanying drawings and the following description. is placed. Other features will become apparent from the description and drawings and from the claims. Brief Description of Drawings Figure 1 is a perspective view of a refrigerator according to a first embodiment.

Figure 2 According to the first embodiment, a refrigerator compartment door is partially opened. Figures 5 and 6 SekHiB is a perspective view of the refrigerator.

According to the first embodiment, a refrigerator compartment door, ice compartment door It is clearly a perspective view.

According to the first embodiment, the ice making mechanism of a refrigerator compartment door This is a perspective view with the ice removed from the bin.

Perspective views of the ice making apparatus according to the first embodiment.

A perspective view of an ice box according to the first embodiment.

It is an opened perspective view of the ice box.

An opened perspective of an ice extractor in a refrigerator according to the invention is the view.

It is the front view of the rotating blade of the ice box.

The ice extractor includes a fixed blade and an on/off switch of the ice box. front view of the element.

This is the front view of the on/off element in Figure 11.

A front view showing the inside of the ice box.

This is the bottom view of the ice box.

It is the plan view of the ice box.

The first embodiment is a vertical section view of the refrigerator compartment door.

An ice maker is rotated to separate the ice from the Figure 16 ice maker. A front view of a situation where pieces of ice are being removed from the ice box.

A front view of a situation where ice cubes are removed from the ice box.

According to a second embodiment, it is a perspective view of a refrigerator. A third embodiment is a perspective view of a refrigerator.

A fourth embodiment is a perspective view of a refrigerator.

Detailed Description of Concrete 'Examples' Now, with detailed reference to concrete examples of the present description, examples of which are shown in the accompanying drawings. will be found.

Figure 1 is a perspective view of a refrigerator according to a first embodiment. Figure 2, According to the first embodiment, a refrigerator compartment door is partially opened. It is a perspective view.

Figures 1 and Ziye atifla, according to this concrete example, a refrigerator (1) shows the exterior of the refrigerator. a cabinet (10) defining it and the refrigerator doors (11) movably attached to this cabinet (10) and 14).

A storage compartment is defined in the cabinet (10) for storing food. storage compartment, a refrigerator compartment (102) and a freezer compartment located below the refrigerator compartment (102) (104) includes.

In other words, in this concrete example, it is placed on top of the freezer compartment of a refrigerator compartment. A bottom freezer type refrigerator will be described.

The refrigerator door (11 and 14) is used to open and close the refrigerator compartment (102). a freezer compartment door (11) and freezer compartment (104) for opening and closing compartment door (14).

The refrigerator compartment door 11 includes several doors 12 and 13 on the left and right sides, respectively.

These doors 12 and 13 are a first refrigerator compartment door 12 and a first refrigerator compartment a second refrigerator compartment door (13) located on the right side of the door (12). First refrigerator compartment door (12) independently of the second refrigerator compartment door (13) it can move.

The freezer compartment door (14) includes several doors (15 and 16) arranged vertically. This doors (15 and 16), a first freezer compartment door (15) and a first freezer compartment a second freezer compartment door (16) located on the underside of the door (15). first and The second refrigerator compartment doors 12 and 13 are rotatably movable and the first and second freezer compartment doors (15 and 16) can be moved by sliding.

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

One door (12 and 13) of the first and second refrigerator compartment doors is fitted with a water or ice dispenser. distributor (17) can be placed. For example, the dispenser (17) is attached to the first refrigerator door (12) in Figure 1. can be placed. It is also attached to a door of the first and second refrigerator compartment doors 12 and 13. an ice maker (described later) for forming and storing ice cubes can be placed.

In this embodiment, the dispenser 17 and the ice maker are connected to the first refrigerator compartment door (12) and it can be placed on the second refrigerator compartment door (13). Therefore, below, the dispenser (17) and the ice The case in which the making device is placed on the refrigerator compartment door (11) will be described. This In the document, the first refrigerator compartment door (12) and the second refrigerator compartment door (13) It is called the refrigerator compartment door (11).

Figure 3 shows a refrigerator compartment door according to the first embodiment, with the ice compartment door open. It is a perspective view. Figure 4 is a refrigerator compartment according to the first embodiment. is a perspective view of the door with the ice maker removed from the ice compartment. an attached door trim 112. The door trim (112) is a part of the refrigerator compartment door (11). defines the back surface.

The door trim 112 defines an ice chamber 120 . To create and store ice cubes, The ice maker (200) is located inside the ice compartment. Ice compartment 120, one ice compartment It opens and closes with its door (130). The ice compartment door 130 is closed by a joint 139. it is connected to the coating (112) in a rotational manner. With the ice compartment door (130) of the ice compartment (120) a lever 140 attached to the door trim 112 to the ice compartment door 130 when it is closed. is placed.

In the door trim 112, a lever connector (128) for attachment to a portion of the lever 140 is defined. The arm connector 128 receives this portion of the arm 140.

The cabinet (10) has a main body supply duct (108) for supplying cold air to the ice compartment (120) and a main body return duct (108) to recover cold air from the ice chamber (120) includes. The main body supply channel (106) and the main body return channel (108) are inserted into an evaporator. (not shown here) can communicate with a space inserted.

Refrigerator compartment door (11), main body supply channel (106) cool air a door feed duct (122) for supplying the ice compartment (120) and a door return channel for sending air to the main body return duct 108 for recovery. includes channel 124.

The door feed duct 122 and the door return chute 124 are one outer part of the door trim 112. extends from wall 113 to an inner wall 114 forming the ice chamber 120. door feed channel (122) and the door return channel (124) are set vertically and the door feed channel (122) It is placed on the return channel (124). However, in this embodiment, the door feeder channel The positions of (122) and door return channel (124) are not limited to these.

When the refrigerator compartment door (11) closes the refrigerator compartment (102), the door feed duct The (122) aligns and communicates with the main body feed channel (106) and the door return channel (124) on the other hand, it aligns and communicates with the main body return channel (108).

The ice compartment (120) connects the cold air flowing in the door supply channel (122) to the ice making mechanism. (200) a cold air duct (290). Cool air duct (290), cool air inside includes a flowing passage, and the cold air flowing in the cold air duct 290 is ultimately ice-making is fed to the assembly (200). Thanks to the cold air duct (290), ice making of cold air Since it is possible to condense cold air into the assembly 200, the ice cubes are quickly can be created in sequence.

The refrigerator compartment door (11) is used to provide an electrical source to the ice maker (200). a first connector 125. The first connector 125 is exposed to the ice chamber 120 .

The refrigerator compartment door (11) is equipped with a water supply unit to supply water to the ice maker (200). conduit (126).

The water supply pipe (126) is placed between the outer casing (111) and the door trim (112) and its end is inserted into the door. passes through the cover 112 and is placed in the ice compartment 120.

On the underside of the inner wall 114 of the door trim 112 forming the ice compartment 120, the ice An ice opening 127 is placed to remove the cubes. One that communicates with the ice opening (127) the ice channel 150 is located on the underside of the ice chamber 120 .

Hereinafter, the construction of the ice maker will be described in detail.

Figures 5 and 6 are perspective views of the ice making apparatus according to the first embodiment.

Referring to Figures 3 to 6, the ice maker (200) contains areas where the ice cubes will be formed. defines and an ice maker (210) supporting the formed ice, the ice cubes from the ice maker A drive that provides power to automatically rotate the ice maker 210 to remove 210 When water is supplied to the icemaker (210), it turns off the icemaker (210) to prevent excessive water flow. a cover (230) and water supply pipe (126) that directs water to the ice maker (210). a water diverter (240).

The ice maker 200 includes a housing piece 215 on which the ice maker 210 is placed. a support mechanism 250, an ice block that stores the ice cubes removed from the ice maker 210 box (300), a full ice sensor (270) that detects the full ice condition of the ice box (300), and ice box (300) includes a motor assembly 280 optionally connected to the box 300.

An electrical wire connected to the motor assembly 280 and an electrical wire connected to the drive source 220 wire to a second connector (282) removably connected to the first connector (125). it connects.

In detail, the drive source 220 may include a motor.

The support mechanism 250 is connected to a first support member 252 and a first support member 252. a second support member 260 attached.

The first support piece 252 is placed in the ice chamber 120 . Engine assembly 280, primary it is attached to the support piece (252). From the ice box to the bottom surface of the first support piece 252. An ice opening 253 is placed through which the extracted ice cubes (300) pass. Ice box (300) it is placed on the first support member 252. In other words, the first support piece 252 is ice. box (300).

When the ice box 300 is placed on the first support member 252, the motor assembly 280 it is connected to the box (300). In this embodiment, the ice box 300 is attached to the first support piece 252. The state in which it is placed means the state in which the ice bin 120 carries the ice bin 300.

The housing piece (215) on which the icemaker (210) is placed is attached to the second support piece (260). gets stuck. The icemaker 210 includes a rotating shaft 212 on one side. Rotary shaft (212) to housing piece (215) is connected in a rotary manner. To the other side of the ice maker (210), from the gear case (224) an extending extension piece (not shown here) is connected.

Full ice sensor 270 to second bracket 260 in a separate position from ice maker 210 gets stuck. The full ice sensor 270 is placed under the ice maker 210.

The full ice sensor 270 consists of a transmission piece 271 that transmits a signal and from this transmission piece 271. a receiving part 272 spaced apart and receiving a signal from the transmitting part 271. transmission when placed in the inner area of the ice box (300).

Hereafter, ice box 300 will be described in detail.

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

Referring to Figure 7 , an opening 310 is defined on an upper side of the ice box 300. ice box Supporting the ice cubes and keeping the stored ice cubes a sloping guiding surface into the ice box (300) to guide it to slide is placed.

An ice storage area (315) in which ice cubes are stored, 'front wall (311), rear wall (312), side are defined by walls 313 and inclined guiding surface 320.

Inclined guide surface 320, a first inclined guide surface 321, and a second inclined guide surface includes a guiding surface (322). The first inclined guiding surface 321 is one of the side walls 313. it slopes down from the wall to a middle part. Second inclined guiding surface (322), side it slopes down from the other wall of the walls (313) towards the middle part.

In order to take the ice cubes taken into the ice box (300) out of the ice box (300), the first An ice is placed between the inclined baffle surface (321) and the second inclined baffle surface (322). extractor 400 is placed. That is, the first inclined guiding surface (321) and the second inclined the guiding surface 322 is placed on the left and right sides of the ice extractor 400.

The ice extractor 400 is a predetermined area (411) in which the ice cubes are to be placed. includes at least one rotating blade (410) to define it. The ice extractor (400) removes ice cubes. may include a set of rotating blades 410 for easy removal.

Next, the ice extractor 400 comprising this set of rotating blades 410 is exemplary. will be described.

Ice placed on the first inclined guiding surface (321) and the second inclined guiding surface (322) cubes move towards the ice extractor 400 with their own weight. Then ice cubes are ejected by an action of the ice extractor 400.

Ice extractor 400, first inclined guide surface 321, and second inclined guide surface (322) in a rotational manner. In addition, the final ice cubes a discharge piece 500 having a discharge opening 510 from which it is positioned between the guiding surface (321) and the second inclined guiding surface (322).

The ice ejector (400) moves forward/backward and rotationally onto the discharge piece (500). placed in such a way that it can move.

When the ice extractor 400 is rotated in a first direction, it is used to break the ice cubes. at least one fixed blade 480 interacting with the rotating blades 410 (400) is placed on one side of a lower part, ie, on one side of the discharge piece 500.

A set of fixed blades (480) is attached to the ice box (300) for easy breaking of the ice cubes. can be placed. Next, the ice box 300 containing the set of fixed blades 480 is taken as an example. will be described.

The set of fixed blades 480 are spaced apart and the rotating blades 410 are it passes through a gap between the group of blades 480.

As a result of the rotation of the rotating blades (410), the ice is formed by the fixed blades (480) and the rotating blades. (410) to form ice chunks when compressed between breaks down.

When the ice extractor 400 is rotated'L'ig'L' in a second direction opposite to the first direction, the ice Optional with drain opening (510) and ice storage area (315) for removing cups an on/off element 600 communicating with the bottom of the ice removing element 400 It is placed on one side of the part, in other words, on the side of the discharge part (500).

Limiting the operating range of the on/off element 600 so that the ice cubes are overloaded. limit an operation below the on/off element 600 to prevent it from being removed in such a way. part (650) is placed.

The ejector 500 is a structure that corresponds to a rotational track of the rotating blade 410. a discharge diverter wall 520. Fixed blades (480), dump routing wall 520 is placed under it.

Discharge baffle wall 520 at discharge part 500 of crushed ice chips. prevents it from happening. The rotating blades (410) of the ice cubes and the front wall of the ice box (300) (311) on a rear surface of the front wall (311) of the ice box (300) to prevent it from being pinched between (312), an ice jam prevention member (330) protruding toward the rotating blade (410) is placed.

Figure 8 is an opened perspective view of the ice box.

Referring to Figures 7 and 8 , the assembly of rotary blades 41 0 is fixed to an axis of rotation 420. Rotation axis (420), a support plate (425), and motor assembly (see reference number in Figure 6). stretches horizontally.

The assembly of rotating blades 410 is in a direction parallel to a longitudinal direction of the axis of rotation 420. spaced apart from each other.

The axis of rotation 420 is attached to one side of each of the set of fixed blades 480. Another so to speak, the axis of rotation 420 passes through the group of fixed blades 480. On the corresponding fixed blades (480), An through hole 481 is defined through which the axis of rotation 420 passes.

Here, the through hole 481 may have a larger diameter than the diameter of the axis of rotation 420 and so that the fixed blades 480 do not move when the rotation axis 420 is rotated.

The group of rotary blades 410 and the group of fixed blades 480 are alternatively 420 may be located in a direction parallel to its longitudinal direction.

As described above, the other side of each set of fixed blades 480 is it is fixed to an underside of the baffle wall 520. A fastening element (485) It attaches to the other side of the blades 480 and is connected to a defined one on the discharge routing wall 520. It is attached to the groove (521).

One or more on/off elements 600 may be provided. on/off element (600), the fixed blades 480 are placed on a lateral side of the assembly.

The on/off member 600 is rotatably placed on the discharge piece 500.

The on/off member 600 may be made of an elastic material or may be made of an elastic material such as a spring. may be supported by element 640.

This is due to the compression effect of one end of the on/off member 600 from the ice cubes. on/off when a compression effect has passed when it moves downwards This is done for the element (600) to return to its starting position.

The ice extractor (400), the fixed blade (480), and the on/off element (600) (300) and then a front plate forming the front wall (311) of the ice box 300. (311a) is placed.

To prevent the opening/closing element (600) or the fixed blade (480) from being exposed to the outside environment. For this purpose, a cover member 318 may be provided on a portion of a front surface of the front plate 311a.

Figure 9 is an exploded perspective of an ice extractor in a refrigerator according to the invention. is the view.

Referring to Figures 7 to 9, the support plate to flexibly support the anchor plate (428) Between (425) and the junction plate (428), a flexible element (429) having the shape of a coil is placed. axis 420 and an attachment member 421 is attached to a front end of rotation axis 420.

Motor assembly (see figure ref number 280), mounting plate (428) by choice a connector (281) that connects. A mounting plate (428) A protrusion 430 with element 281 attached is placed.

In a situation where a user is taking the ice box 300 into the ice compartment 120, the protrusion 430 and When both ends of fastener (281) are aligned with each other, fastener (281) it does not get caught in the ledge 430. In this case, the baffle plate (428), the resilient member (429) It is moved towards the support plate (425) by the

Next, the alignment between both ends of the fastener 281 and the protrusion 430 is removed by a continuous process of the motor assembly (see Figure Food reference number 280) when, the connecting plate (428) is moved back by the flexible member (429) and this Therefore, both ends of the fastener 281 are attached to the protrusion 430.

Support plate 425 rotates ice cubes placed on a lateral surface of support plate 425. a curved surface (426) to smoothly move it towards the assembly of blades (410). has.

Figure 10 is a front view of the rotary blade of the ice box.

Referring to Figure 107a, the respective rotary blades 410 have a middle section through which the axis of rotation 420 passes. It includes extension portions 413 that extend ultimally from 412 and middle portion 412.

In the middle portion 412, an through hole 415 is defined through which the axis of rotation 420 passes. Open the hole smoothly transmits a rotational force of the axis of rotation (420) to the middle portion (412). It may have a non-circular shape or an elongated hole shape.

The set of extension pieces 413 may be spaced apart from one another. Two adjacent extensions A space (411) is defined between the piece (413) in which ice cubes are stored.

The respective extension portions 413 extend from the middle portion 412 outward to a gradually increasing width. has. Extension to prevent excessive flow of ice cubes stored in cavity (411) a hook piece (416) is placed at one end of the piece (413).

Therefore, in a situation where the ice cubes are taken into the void (411), the rotary blade (410) rotates. When the ice cubes on the longer part of the extension (413) cling and with the rotating blade (410) Together, the rotating blade 410 moves in one direction of rotation.

Push to one side of the extension piece 413 to break the ice by interacting with the fixed blade 480. A shredding part with sawtooth shape is placed.

While the ice cubes are kept as ice cubes, the ice cubes in front of the crushing part (418) There is a flat surface on the other side of the extension piece (413) for it to move to the other side. This Therefore, the segmenting portion 418 of one extension 418 is the other extension 411 in a space. It is placed on one side opposite the flat surface of the piece (418).

Figure 11 shows the ice removal element, a fixed blade and an on/off element of the ice box. is the front view.

Referring to Figure 11 , when the rotary blade 410 is coupled to the rotation axis 420, the rotary blades The (410) group does not overlap completely, but is slightly bent from front to back. is put in the row.

In other words, when viewed from a front, the group of rotating blades 410 is completely upper it does not overlap but is a swivel in which the rear rotating blade (410) is rotated at a predetermined angle. situation is placed.

The rotary blades 410 are in a completely overlapping relationship in the front and rear directions. the rotating blades (410) set in the first direction for crushing the ice cubes. When it is rotated, the pressure applied to the ice cubes dissipates. As a result, ice cubes it is difficult to break down.

However, as described above, the rotary blades group has a predetermined If placed sequentially in a state where they rotate at an angle, the ice cubes will rotate first. the blade (410) comes into contact with the shredding part (418) and thus it shatters. After that, the crushing ice cubes sequentially with the crushing part (418) of the second rotary blade (410) and followed by the shredding section (418) of the third rotating blade (410) for a predetermined time. contacts within range.

Therefore, in order to significantly increase the ice crushing efficiency, it is necessary to use the ice extractor The rotational force 400 may be concentrated in the respective shredding portions 418.

At the same time, the saw-tooth-shaped shredding section (488) is used for crushing ice cubes. fixed blade (480).

The on/off member 600 is placed on a lateral aspect of the fixed blade 480. Opening and closing a return member (605) whose element (600) is rotatably inserted into the ice box (300). includes. The return member 605 is formed by the resilient member 640 having the form of a torsion spring. flexibly supported. The flexible member 640 has a tip attached to the ice box 300 and of the on/off member 600 to flexibly support the on/off member 600. 600 has another end that fits on one surface.

The on/off member 600 has a rounded first guide surface 610 and a turning has a second guiding surface (612) attached to the part (605). At this moment, the second orientation surface 612 and the second inclined guiding surface (see reference number 322 in Fig. 7), continuous creates a surface.

Figure 12 is a front view of the on/off element of Figure 11 .

Referring to Figures 6 and Member, more than one on/off element 600 may be provided.

The group of on/off elements 600 act independently of each other.

If a single on/off element 600 is placed in the ice box 300, the other ice cubes are space and in this space, ice cubes are not removed and only on/off There is no ice when the element (600) stays on a part of the first orientation surface (610).

However, there are multiple on/off elements 600 within the ice box 300. case, the ice cubes cling to an on/off element (600) and actuate the on/off element (600). even if it causes it to remain on, other devices that do not have ice cubes attached The on/off element (600) is closed to prevent unnecessary removal of ice cubes. can maintain the situation.

In this case, each of the on/off elements 600 may be fitted with a flexible element 640.

The corresponding on/off element 600 is located between the on/off elements 600 of the ice cubes. It rotates when each of the on/off elements (600) is in the closed state. includes a hooked jaw (615) to prevent the assembly of blades (410) from protruding.

The hook jaw 615 may be located at one end of an upper surface of the first guiding surface 610.

Figure 13 is a front view showing the inside of the ice box and Figure 14 is a front view of the ice box. is a bottom view.

Referring to Figs. 6 to 14, the first inclined guiding surface (321) is to the group of fixed blades (480). placed adjacent. Second inclined guide surface (322), adjacent to on/off element 600 is placed.

A discharge diverter wall 520 connected to the first inclined baffle surface 321 It is placed on one side of the piece (500). The second inclined guiding surface is divided into two parts. This, second inclined towards the ice extractor 400 to prevent the ice cubes from breaking for adjusting the speed of movement of ice cubes moving along the guide surface (322) makes.

The second inclined guiding surface (322) is the outer edge attached to the side walls (313) of the ice box 300. an outwardly sloping guiding surface (322b) and an outwardly sloping guiding surface (322b) an inward sloping guide connected to and placed adjacent to the ice extractor 400 surface (322a).

Inwardly sloping guiding surface (322a) It is inclined at a smaller angle than the angle. Therefore, the outwardly inclined guiding surface The velocity of the ice cubes moving along (322b) is determined by the inwardly inclined guiding surface. (322a) decreases. The second guide surface 612 of the on/off element 600 is inclined inward. inclined inward to form a continuous surface with the guiding surface (322a) placed at one end of the guiding surface (322a).

When the on/off element 600 closes the discharge opening 510, the second direction surface 612 and the inclined guiding surface (322a) determine the speed of movement of the ice cubes. It creates a continuous surface to reduce

When the on/off member 600 opens the discharge opening 510, the second guide surface (612), a downward motion to guide the ice cubes towards the discharge opening (510). it does. An inclined endpoint (321a) of the first inclined guiding surface 321 is placed in a position higher than the position of the rotation axis (420) of the element (400).

This means that the pieces of ice cubes that have been shattered in a position where the fixed blade 480 are This is done to prevent it from moving upwards.

Drain diverter wall to prevent fragments of crushed ice cubes from remaining 520 may have a slope corresponding to the slope of the rotation track of the rotary blade 410.

At the same time, the second inclined guiding surface is used to keep the ice cubes in the form of ice cubes. 322 may be inclined at an angle smaller than the angle of the first inclined guiding surface 321.

The inwardly sloping guiding surface 322a of the second sloping guiding surface 322 is a continuous the angle of the second guiding surface 612 of the on/off element 600 to form the surface It can be inclined at the same angle to a large extent.

The rotational part 605 of the on/off member 600, the rotation of the ice extractor 400 it is placed in a lower position than the position of its axis 420; Thus, the second inclined the guiding surface 322 is smaller than the angle of the first inclined guiding surface 321. it tilts at the angle.

To limit an opening angle of the opening/closing element 600, an action constraint part (650) is placed under the on/off element (600).

Process limiter 650, vertically placed first tooth (651), from first tooth (651) a second tooth 652 and a first tooth 652 spaced apart and higher than the first tooth 651 an inclined contact piece connecting an upper part of the thread 651 to an upper part of the second thread 652 (653) includes.

The on/off member 600 stops in contact with the contact portion 653.

As described above, the on/off member 600 may be provided in more than one. Same At the same time, the opening/closing element (600) has different maximum opening angles, respectively. may have.

Figure 15 is a plan view of the ice box. is placed inside. The anti-ice jam piece (330) is removed from the front wall of the ice box (300). (311) protrudes or extends inward.

The anti-ice trap (330) is located at the very front of the rotating blades (410) assembly. it is placed in a space between the rotating blades (410) and the front wall (311).

The anti-ice jam piece (330) is placed 'on top of a section from which crushed ice cubes are removed. can be placed.

Figure 16 is a d'usey sectional view of the refrigerator compartment door of the first embodiment, and Figure 17 is an ice maker rotated to separate the ice from the Figure 16 ice maker. It is placed substantially vertically below the icemaker 210 in a state in which it is present. placed in a lower position. Therefore, the ice compartment door (130) It is not placed in a first region (A) between In other words, the ice box 300 is the A first link between the ice compartment door 130 and the ice maker 210 in an entire region of 120 can be placed in a second region 'excluding the region'.

The reason this is done is because the ice maker (210) rotates the ice cubes into the ice cubes (I). by its own weight it will separate it from the ice maker (210) so that they do not fall into the ice box (300). the ice box (300) in the first region (A) of the ice box (300) as it is adjusted to provide unloading is not required. In other words, ice cubes (l) leaving the ice maker 210 Since it does not pass through the first zone (A), the ice box does not need to be placed in the first zone (A).

Therefore, since the ice box 300 is not placed in the first zone A, the ice compartment door 130 is may be placed further adjacent to the constructor 210. As a result, the total of the refrigerator compartment door (11) thickness can be reduced. In other words, the refrigerator compartment door (11) may be thin.

This is done because the rotating shaft 212 of the ice maker 210 is inside the ice box 300. the volume of the ice compartment 120 when placed parallel to the axis of rotation (420) is the increase.

The assembly of rotating blades 410 is in a direction parallel to the longitudinal direction of the rotation axis 420 can be spaced apart from each other. The assembly of rotating blades 410 is a front of the icemaker 210. can be placed within the rear width (W) range.

Therefore, the ice maker 210 is rotated to separate the ice cubes l from the ice maker 210. When a portion of the group of ice cubes leaving the ice maker 210, the rotating blades (410) falls on at least one doner blade of the group. In other words, the ice leaving the ice maker 210 cubes (I) fall with their own weight and at least one of the falling ice cubes (l) turns at least one it contacts the blade (41 O).

In this case, a falling direction of the ice cubes I leaving the ice maker 210 is that of the axis of rotation. (420) intersects with its longitudinal direction. In another direction, the ice leaving the ice maker 210 The falling direction of the cubes (I) is greater than the actual surface defined when the group of rotating blades (410) rotates. proportionately parallel.

The horizontal distance from the ice compartment door 130 to the rotating shaft 212 of the ice maker 210, from the shortest horizontal distance from the ice compartment door (130) to the discharge opening (510) is big.

From here on, the motion process of the ice cubes formed in the ice making assembly is described. will be.

Figure 18 is a front view of a situation where pieces of ice are removed from the ice box, and Figure 19 is is a front view of a situation where ice cubes are removed from the ice box.

The process of removing the formed ice cubes will be described with reference to Figures 16 to 185.

To separate the ice cubes from the ice maker 210, a process signal is sent to the drive source 220. When entered, the drive source 220 operates. The power of the drive source 220 is the one of the ice maker 210. It is transmitted to the ice maker (210) by the gear box (224) to rotate as a whole.

In this embodiment, the ice cubes are separated by the torsional action of the ice maker 210. of ice maker When 210 is torsioned, one end of the ice maker 210 and the other end are forced into their own movements. twists accordingly. Therefore, the ice cubes leave the ice maker 210. Torsion of the ice maker (210) Since the principle of its operation is well known, detailed descriptions will not be made. through the ice box (300).

As described above, some of the ice cubes leaving the ice maker 210 It can fall on the (410) group; another part of the ice cubes first inclined orientation surface (321) may fall on it and another portion of the ice cubes may fall on the second inclined orientation. surface (322).

To remove crushed ice pieces, the ice extractor 400 is rotated in the first direction. (See Fig. 18 counterclockwise), the rotary blades (410) assembly portion 418 approaches the cutting portion 488 of the fixed blade 480.

Therefore, the ice cubes in the cavity 411 of the rotating blades 410 assembly It is placed on the fixed blade (480) with the rotation of the blades (410). In this concrete example, in space (411) ice cubes that fall directly on the rotating blades (410) group, or there may be ice cubes sliding along the first inclined guiding surface 321.

In this case, when the assembly of rotary blades 410 is rotated continuously in the first direction, the rotary blades 410 The jammed ice cubes break apart. The crushed ice chips fall in the direction of the discharge opening (510) and is taken out.

Keeping the on/off element 600 in the closed position during the ice removal process, The second inclined guiding surface 322 may prevent the removal of ice cubes located on it.

In the process of removing the ice cubes, the ice extractor 400 is rotated in the second direction. (clockwise as viewed in Figure 18), in the space of the rotating blades (410) group (411) The ice cubes contained in the machine are formed by the rotation of the rotating blades (410) and the on/off element (600). moves in the direction Ice cubes in the cavity (411) of the rotating blades (410) assembly, directly rotating blades Ice cubes falling on group (410) or along the second inclined guiding surface (322) It could be floating ice cubes.

When the group of rotary blades (410) is rotated continuously in the second direction, the respective rotary blades The extension piece (410) (413) pushes the ice cubes on the on/off element (600).

As a result, the turning blades 410 are attached to the on/off element 600 by the ice cubes. compressive forces are applied.

For this reason, the on/off element 600 is used to compress ice cubes and rotating blades 410. It is rotated downwards with the force (see Figure 19=counterclockwise). As a result, one end of the extension piece (413) of the respective rotating blades (410) and the opening/closing element (600) A gap is defined between one end. Then the ice cubes go into the void and finally the ice cubes are taken out.

When the ice removal element 400 stops rotating, the applied to the on/off element 600 As the pressure is relieved, the on/off member (600) allows the flexible member (640) to flex. It returns to its starting position thanks to its force.

A summary of the movement of the ice cubes in the ice box 300 is given below. rotary blades The ice cubes falling on the (410) group move downwards when the rotating blades (410) group rotates. it moves.

Ice cubes falling on first inclined guiding surface (321), rotating blades (410) assembly when it turns in the first direction, it goes into the void (411) with its own weights. Rotary blades (410) When the group rotates, the ice cubes in space (411) move downwards.

At the same time, ice cubes falling on the second inclined guiding surface (322), rotating blades When the group (410) turns in the second direction, it goes into the void (411) with its own weights. rotary blades When the group (410) rotates, the ice cubes in the space (411) move downwards.

Mostly ice cubes, rotary blades on the respective inclined surfaces (321 and 322) It does not move when the (410) group is stopped.

Consequently, according to this embodiment, the stored ice cubes are placed in an additional container in the ice box 300. Thanks to the rotation process of the rotating blades (410) group without the need for a transfer unit is taken out.

At the same time, the ice cubes in the ice box 300, the reciprocal movement between the ice cubes. except from the top to the bottom only, ie from the inlet of the ice box (300) (301 a) is moved towards the discharge opening (510). When and its output (154) overlap each other, a common overlap region is formed. Therefore, ice The movement path of the cubes is minimized.

The technical significance of this embodiment according to the above-described structure will be described below.

As described above, the ice cubes in the ice box go from the top to the bottom and the thickness of the ice box as it is moved and dropped by the rotating set of blades. can be reduced.

In this concrete example, the thickness of the icebox is relative to the longitudinal axis of the icebox's rotational axis. indicates the thickness in the direction.

Ice according to the reduction in thickness of the ice box and the method of separating the ice cubes from the ice maker thickness of the refrigerator compartment door, thanks to the position of the box in the ice compartment. can be reduced.

When the thickness of the refrigerator compartment door is reduced, do not insert the food into the refrigerator compartment door. An additional basket can be placed.

In addition, when the thickness of the refrigerator compartment door is reduced, the refrigerator compartment because the volume of a part of the door (attached to the refrigerator compartment) will decrease, the refrigerator compartment material can be increased.

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

This embodiment, with the exception of the type of refrigerator and the position of the ice maker. It is the same as the first concrete example. So now only specific parts of this concrete example are described. will be.

Referring to Figure 20, this embodiment includes a refrigerator 70, a refrigerator compartment 712 and a a side-by-side type refrigerator in which the freezer compartment (714) is placed on the left and right side respectively it could be.

The freezer compartment 712 is opened and closed by the freezer compartment door 720 and the refrigerator compartment 714 is opened and closed by a refrigerator compartment door 730.

The refrigerator 70 includes an ice maker 740 for forming ice cubes.

The ice maker 740 consists of an ice maker (750) and ice maker for forming ice cubes. The 750 includes an ice box 760 for storing the separated ice cubes.

In this embodiment, excluding the positions of the ice maker, ice maker and ice box. has the same structure as in the first concrete example.

The ice maker (750) is placed in the freezer compartment (712) and the ice box (760) is placed in the freezer compartment. It is placed on the door (720) in a removable way. Freezer compartment door (720) freezer When closing compartment 712, ice box 760 is placed under ice maker 750.

According to this concrete example, thanks to the advanced structure of the ice box, the freezer compartment door thickness can be reduced.

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

This embodiment is compared with the second embodiment, excluding the position of an ice making device. is the same. Therefore, only specific parts of this concrete example will now be described.

Referring to Figure 21.9, this embodiment includes a freezer compartment door (770), an ice compartment (774). a door skin 772 defining it. Ice bin (774), an ice maker (780) includes. In this embodiment, the ice maker 780 is of the same construction as in the first embodiment. has. According to this embodiment, the operation of the ice maker described in the first embodiment and the ice Thanks to the advanced structure of the box, the thickness of the freezer compartment door can be reduced.

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

This embodiment is compared with the second embodiment, excluding the position of an ice making device. is the same. Therefore, only specific parts of this concrete example will now be described.

Referring to Figure 22 , a bottom freezer type refrigerator will be described as an example. Refrigerator An ice box (860) is placed in one of the compartment doors (820 and 830). making an ice other components of the assembly (eg, an ice maker (850)), excluding the ice box (860), freezer It is placed in the chamber (812).

From the refrigerator compartment (812) of an area where ice cubes are formed to the refrigerator compartment (812) A first insulating enclosure (870) is placed to insulate it. Ice maker (850), primary insulation box (870) is inserted into it. A bottom surface of the first insulating box 870 can be opened so that the ice ice cubes created in the maker 850 may fall down.

At the same time, a second insulating case receiving the ice box 860 on the refrigerator compartment door (880) is inserted. A top surface of the second insulating box 880 can be opened to receive ice cubes.

When the refrigerator compartment door closes the refrigerator compartment, the second insulating case it comes under the insulation case.

In this case, there is a base surface of the first isolating case 870 and a joint of the second isolating case 880. from the first and second insulating casings (870 and 880) to insulate a gap between the upper surface. a piece of insulation (not shown here) can be placed on one of them.

According to this concrete example, the thickness of the refrigerator door due to the advanced structure of the ice box can be reduced.

According to the suggested concrete examples, the ice cubes in the ice box go from the top to the bottom. and as it is moved and dropped by the rotating set of blades, the thickness of the ice box can be reduced.

At the same time, reducing the thickness of the ice box and separating the ice cubes from the ice maker refrigerator compartment, thanks to the position of the ice box in the ice compartment according to the The thickness of the door can be reduced.

When the refrigerator door is thin, an additional basket will be placed on the refrigerator door to hold the food. can be placed.

Also, when the refrigerator door is thin, part of the refrigerator door (storage material receiving capacity of the storage compartment, as the volume of the part (the part attached to the compartment) will be reduced.

Claims (6)

REQUESTS A cabinet (10) having a storage compartment, a refrigerator comprising: a refrigerator door (11) that opens and closes the storage compartment; an icemaker (210) defining an area for forming ice; an ice box (300) mounted on the refrigerator door and placed under the icemaker (210) to receive the ice formed in the icemaker (210); a drain hole (510) located in the bottom of said ice box (300); a motor assembly (280) provided on the refrigerator door (11) and including a fastener (281); an ice extractor 400 inserted into the ice box 300 for optional removal of ice from the ice box 300 and comprising: an axis of rotation (420) disposed horizontally within the ice box 300; a group of rotating blades (410) fixed to the axis of rotation (420) and spaced apart from each other in a longitudinal direction of the axis of rotation (420); a group of fixed blades (480) interchangeably disposed with the group of rotating blades (410) in the longitudinal direction of the axis of rotation (420); the ice extractor further comprising: a connecting plate (428) optionally connected to the connector (281); a backing plate (425) in the mounting plate (428) for attachment to the fastener (281); the axis of rotation (420) passing through the base plate (428) and the support plate (425); the unloader 400 includes a resilient member 429 placed between the backing plate 425 and the anchor plate 428 to flexibly support the anchor plate 428, and that the (410) includes an inclined surface (426) to be moved towards the group. 5 2. It is a refrigerator according to claim 1, Its feature is; the ice box (300) comprising: a front wall (311); a rear wall (312); and the side walls (313) connecting the front wall (311) and the side ends of the rear wall (312), defining an opening (310) on an upper side of the ice box (300), a rotating blade located at the very front of the rotating blades (410) 10 assembly and placing an ice entrapment prevention member (330) in a space between a rear surface of the front wall (311). 3. It is a refrigerator in accordance with claim 25, its feature is; the ice box 300 further comprising: a first inclined guiding surface 321 sloping down one wall of the half walls 313 towards a middle 15 portion of the ice box 300; a second inclined guiding surface (322) sloping down one wall of the side walls (313) towards a middle portion of the ice box (300); and a discharge guide wall (520) having a slope corresponding to a slope of a rotation track of the rotating blade (410). 20 4. A refrigerator according to claim 3, its feature is; the first inclined guiding surface (321) is placed on the rotation axis (420) of an inclined end point (321a). 5. It is a refrigerator according to claim 1, its feature is; an attachment member (421) is attached to a front end of the axis of rotation (420). 6. It is a refrigerator according to claim 1, its feature is; Each blade 25 in the group of rotary blades 410 includes: a middle section 412 having an through hole 415 through which the axis of rotation 420 passes, and a group of extensions 413 radially extending from the middle 412 . It is a refrigerator suitable for demand, its feature is; the through hole 415 has a non-circular shape or an elongated hole shape. It is a refrigerator suitable for request and its feature; is the definition of a space (411) in which ice is placed between adjacent extension pieces (413). It is a refrigerator suitable for claim 6, its feature is; each extension in the group of extension pieces (413) has a gradually increasing width from the middle section (412) outward. It is a refrigerator according to claim 6, its feature is; Each extension in the group of extension pieces (413) includes: a cutting portion (418) having the shape of a saw-tooth on one side of each extension piece; a flat surface placed on the other side of each appendage; and a hook portion (416) disposed at one end of the flat surface of each extension portion. It is a refrigerator according to claim 1, its feature is; the flexible element (429) has a coil shape and is connected with the rotation axis (420).