KR101157704B1 - Ice making device and refrigerator having the same - Google Patents

Abstract

An object of the present invention is to provide an ice making device capable of producing ice quickly, and capable of appropriately maintaining a state of ice stored in a storage device, and a refrigerator provided with such ice making devices.

The ice making apparatus 50 of the refrigerator 1 which concerns on this invention is equipped with the ice tray 60, and cool air flows along the opening end surface 61 of the said ice tray 60, and also The flow of cold air surrounds the ice tray 60 by inducing cold air having passed through to the bottom 62 side of the ice tray 60 and flowing along the bottom 62. It is arranged above the storage device 40 to store. And the cold air induction part 71 which guides the cold air which passed the upper part of the ice-making dish 60 to the bottom part 62 side of the ice-making dish 60 is provided, The said cold air induction | conduction part 71 is located above the ice-making dish 60. The cold air passage part 72 which passes a part of cold air which passed through in order to supply to the storage space 41 of the storage device 40 is formed.

Refrigerator, ice maker, cold air, storage space, opening end face

Description

ICE MAKING DEVICE AND REFRIGERATOR HAVING THE SAME}

The present invention relates to an ice maker and a refrigerator having the ice maker.

A deicing plate having a bottom portion and an opening end face is conventionally provided, while cold air flows along the opening end surface of the ice making plate, and cold air passing through the upper portion of the ice making plate is directed to the bottom side of the ice making plate and flows along the bottom portion. For example, an ice making device is known which is configured such that the flow of cold air surrounds the ice making tray, and is disposed above the storage device that stores ice in the storage space (for example, Patent Document 1).

This ice making apparatus is provided with the ice-making chamber which accommodates an ice-making tray, and made it the structure which made the cold air which flowed to an ice-making chamber flow only to the vicinity of an ice-making tray and an ice-making tray. Therefore, there is an effect that the ice making speed can be increased.

Patent Document 1: Japanese Unexamined Patent Application Publication No. 2002-228334

However, since the conventional ice maker does not flow cold air into the storage space of the storage device disposed below the ice maker, there is a problem that the state of ice stored in the storage device cannot be properly maintained.

Specifically, in general, when the freezing compartment is opened, warm air comes in from the outside. The warm air then hits the ice stored in the storage device, resulting in the melting of the ice. In addition, warm air will also stay in the storage space of the storage device.

Even if the freezer compartment is closed in this state, the air remaining in the storage space becomes cold, and it takes some time for the surface of the ice to freeze again. Therefore, there is a problem that the ice melts in the meantime and freezes, resulting in frozen ice masses.

Accordingly, an object of the present invention is to provide an ice making device capable of producing ice quickly and properly maintaining the state of ice stored in the storage device, and a refrigerator having such ice making device.

This invention is made | formed in order to solve the said subject.

That is, the ice supply device and the refrigerator according to the present invention have an ice making tray having a bottom portion and an opening end face, and simultaneously cool air flowing along the opening end face of the ice making tray and pass above the ice making tray. A flow of cold air is formed to surround the ice making tray by guiding toward the bottom of the ice making tray and flowing along the bottom, and the ice making device is disposed above the ice storage device that stores the ice in the storage space. And a cold air induction part for inducing cold air to the bottom side of the ice making dish, wherein the cold air inducing part is provided with a cold air passing part for passing a portion of the cold air that has passed above the ice making dish to the storage space of the storage device. do.

According to the present invention, it is possible to produce ice quickly and to maintain the state of the ice stored in the storage device appropriately.

The ice making apparatus and the refrigerator provided with the said ice making apparatus concerning one Embodiment of this invention are demonstrated.

The refrigerator 1 which concerns on this embodiment has an external appearance as shown in FIG. 1, and has a function which provides water or ice in the dispenser part 10 provided in the door. In addition, this refrigerator 1 is of a type called side by side, and as shown in Fig. 2, the storage compartment has a structure in which the storage compartment is largely divided from side to side.

Next, the internal structure of the refrigerator 1 will be described with reference to FIGS. 2 and 3. In the refrigerator 1, the 1st storage chamber 20 whose storage temperature is 0 degrees C or less, and the 2nd storage chamber 30 whose storage temperature is higher than 0 degreeC are arrange | positioned at the left and right. Specifically, in the refrigerator 1, the first storage compartment 20 on the left side of the refrigerator 1 is a freezer compartment (hereinafter, also appropriately referred to as the freezer compartment 20), and the second storage compartment 30 on the right side of the refrigerator 1 faces up and down. The upper part is divided into the refrigerator compartment 32, and the lower part becomes the vegetable compartment 33. As shown in FIG. The freezer compartment door 21, the refrigerator compartment door 34, and the vegetable compartment door 35 are provided corresponding to the freezer compartment 20, the refrigerator compartment 32, and the vegetable compartment 33.

Next, the first storage chamber (freezing chamber) 20 will be described. The freezing chamber 20 is provided with an ice making apparatus 50 at an upper portion thereof. The ice making apparatus 50 is arranged in the front part of the freezer compartment 20. In addition, the freezer compartment 20 is provided with a storage device 40 for storing the ice produced by the ice making device 50 in the storage space 41. This storage device 40 is provided inside the freezer door 21. As shown in Fig. 3, the storage device 40 has a positional relationship where the ice is picked up from the ice making device 50 below. Specifically, the upper end opening part 42 of the ice storage device 40 is arrange | positioned so that it may become just under the ice drop part 51 of the ice-making device 50. And the storage device 40 will be in the state located below the ice-making device 50 when the freezing compartment door 21 is closed.

3, the cooling fan 22 which supplies cold air in the freezer compartment 20 is provided in the upper position on the back surface of the freezer compartment 20. As shown in FIG. The freezer compartment 20 is provided with a duct 23 for directly supplying cold air from the cooling fan 22 to the ice making apparatus 50.

In addition, as shown in FIG. 2, the second storage chamber 30 includes a water supply tank 36 for supplying water to the ice making apparatus 50. In addition, the piping (not shown) for the ice-making apparatus 50 extends to the outer side of the refrigerator 1 through the refrigerator housing from the water supply tank 36 toward the depth direction of the refrigerator 1, and from there, the back surface And toward the freezer compartment door 21 side along the ceiling surface, through the refrigerator housing from the intermediate position of the ceiling surface to reach the ice making device 50.

Next, the ice making apparatus 50 is demonstrated using FIGS.

The ice making apparatus 50 has an ice making dish 60 having an opening end face (ie, an open top face) 61 and a bottom portion 62, and at the same time, the cold air has an opening end face (of the ice making dish 60). The flow of cold air flows along the bottom portion 62 by flowing cold air that has flowed along the top of the ice tray 60 and flows along the bottom portion 62 of the ice tray 60. It is an ice-making apparatus 50 comprised so that it may be enclosed above the storage apparatus 40 which stores ice in the storage space 41. And the cold air induction part 71 which guides the cold air which passed the upper part of the ice-making dish 60 to the bottom part 62 side of the ice-making dish 60 is provided, The said cold air induction | conduction part 71 is located above the ice-making dish 60. The cold air passage part 72 which passes a part of cold air which passed through in order to supply to the storage space 41 of the storage device 40 is formed.

Below, before describing the cold air passage part 72 etc., the whole structure regarding the ice-making apparatus 50 is demonstrated first.

The ice making apparatus 50 is arranged to surround the ice making tray 60, the ice making housing 80 for accommodating the ice making tray 60, and the bottom portion 62 of the ice making tray 60. And an ice tray enveloping member 70 which guides along the bottom 62 of 60.
The cold air induction part 71 is provided in the one end part of the ice-making dish surrounding member 70, and the cold air induction part 71 includes the cold air passage part 72 and the extension part (cold air accommodating part) 73 mentioned later.

The ice-making device housing 80 has an ice-making space 81 formed therein, and is configured to accommodate the ice-making dish 60. In addition, the icemaker housing 80 has an open lower portion. This open lower part is a portion through which the ice passes when the manufactured ice falls toward the lower storage device 40. In addition, this part becomes the ice drop part 51.

The ice making machine housing 80 fixes the upper portion to the ceiling surface of the freezing compartment 20. A water pipe insertion penetrating portion 82 for penetrating a water supply pipe (not shown) is formed at an upper portion of the ice making device housing 80. The water pipe insertion through portion 82 is constituted by a round hole. Moreover, the cold air suction part 83 for inducing cold air sent from the cooling fan 22 inward is formed in the side part. In addition, a cold air discharge part 84 for discharging cold air from the ice making space 81 is formed. These cold air suction part 83 and cold air discharge part 84 are formed in the same side part of the ice-making apparatus housing 80, and are arranged side by side up and down. In addition, these cold air suction part 83 and cold air discharge part 84 are comprised by the long hole or the slit.

The cold air suction part 83 of the ice making machine housing 80 is arranged to communicate with the duct 23. In addition, the cold air suction part 83 is provided corresponding to the height position of the opening end surface 61 of the ice making tray 60. The cold air carried by the duct 23 flows along the opening end surface 61 of the ice making tray 60. On the other hand, the cold air discharge part 84 is located below the duct 23, and is arrange | positioned so that it may communicate with the storage space in the freezer compartment 20. As shown in FIG.

Moreover, this ice-making apparatus 50 is of a type called what is called an automatic ice-making apparatus, and fills the empty ice tray 60 with water, and after this water freezes, it rotates the ice tray 60, and removes ice, etc. Ice making can be done automatically. As a structure which enables such an operation, the ice-making apparatus 50 is equipped with the drive part 90 which rotationally drives the ice tray 60. As shown in FIG.

The ice making dish 60 has a substantially rectangular shape as seen from the upper surface as shown in FIG. The ice tray 60 is divided into a plurality of ice trays 64 by partitions 63. The ice trays 64 are formed in two rows in the short side direction and four rows in the long side direction. . The ice making part 64 is formed so that it becomes narrower so that it may be downward, and is a substantially rectangular shape seen from the upper surface, and the ice of a substantially trapezoid shape seen from the side surface is manufactured. Specifically, as shown in FIG. 5 and the like, the ice making unit 64 is constituted by a flat surface having an inclined side surface, and a bottom surface is formed by a curved surface. In this ice tray 60, for example, ice having a size of 42 mm x 32 mm x 25 mm can be produced. In addition, the ice making machine housing 80 is provided so that the short side direction of the ice making dish 60 may be parallel with the depth direction of a freezer compartment.

Moreover, the ice making dish 60 is comprised so that the ice may fall by rotating so that the opening end surface 61 may face downward. Specifically, the ice making dish 60 is rotatable about a rotating shaft along the long side direction. More specifically, the rotating shaft is disposed at the central portion in the short side direction. The ice tray 60 is rotatably held at both ends in the long side direction. Specifically, the ice making dish 60 is rotationally driven from a horizontal state (that is, 0 degrees) to a state where the opening end face 61 is almost downward (for example, 160 degrees).

In addition, the drive unit 90 removes the ice in the form of pushing the ice from the ice making unit 64 by rubbing the ice making tray 60. The operation of twisting the ice tray 60 is performed after the opening end face 61 of the ice tray 60 starts to face downward, and specifically, the angle range is the ice tray 60. ) Is in the range of 130 to 160 degrees in the rotation angle.

Next, the ice-making dish surrounding member 70 is demonstrated.

The ice making machine enveloping member 70 is arranged to close the open part of the lower part of the ice making machine housing 80 (that is, the ice drop 51 of the ice making device 50). This prevents cold air from flowing downward from the ice drop portion 51. Moreover, the ice-making space 81 is comprised by this ice-making dish surrounding member 70. As shown in FIG. By the way, the ice-making dish surrounding member 70 is a member which induces cold air to flow along the bottom part 62 of the ice-making dish 60, and can also be specified as a cold air inducing member.

In addition, the ice-making dish surrounding member 70 is rotatably provided so that it may evacuate from the ice drop part 51 at the time of peeling ice in the form which drops ice downward. Specifically, the ice-making dish surrounding member 70 is rotationally driven by the drive part 90. The ice tray 60 and the ice tray surrounding member 70 are configured to rotate integrally.

The ice making tray enveloping member 70 is formed in an arc shape. Moreover, this arc-shaped ice-making dish surrounding member 70 is arrange | positioned concentrically with the rotation center of an ice-making dish. Specifically, the ice-making dish surrounding member 70 is formed in the shape of a rough semicircle having an angular range of about 200 degrees. However, as an ice-making dish surrounding member, the one end part may be formed about 180 degrees shorter than this. In addition, the arrangement | positioning when the position of about 145 degree from the other end side becomes a position horizontal to a rotating shaft is an arrangement | positioning at the time of the icemaking dish surrounding member 70 (at the time of ice-making).

The ice making dish surrounding member 70 is provided so that one end may protrude upward from the ice making dish 60. The cold air that has passed above the ice tray 60 is brought into contact with the portion pushed out upward, and this portion can be identified as a cold air accommodating portion that receives cold air. In addition, the ice-making dish surrounding member 70 has the site | part which opposes the one side part of the cold direction flow direction downstream of the short side direction both sides of the ice-making dish 60. As shown in FIG. Specifically, the ice making dish enveloping member 70 has a semi-circular arc shape, and is provided so that its one end in the radial direction protrudes upward. On the other hand, the other end part in the radial direction of the ice-making dish surrounding member 70 is arrange | positioned below the cold air discharge part 84 so that the cold air discharge part 84 may not be blocked.

And the cold air passage part 72 is formed in the ice-making dish surrounding member 70, as shown in FIG. This cold air passage part 72 passes about 20% of the cold air which passed above the ice-making dish 60 to the storage space 41 of the storage device 40. Accordingly, the remaining 80% of the cold air flows along the ice making tray enclosing member 70 toward the bottom 62 of the ice making tray 60. However, the ratio of the cold air which the cold air passage part 72 passes is not limited to the said numerical value, It can change variously according to the magnitude | size or structure of the ice-making device 50 and the storage device 40. As shown in FIG.

The cold air passage portion 72 is formed along the long side direction of the ice making tray 60. Preferably, the cold air passage 72 is formed over the entire length of the ice making tray 60. In addition, the cold air passage portion 72 is formed to include at least a height position approximately equal to the height position of the opening end surface 61 of the ice making tray 60.

The cold air passage portion 72 is formed over a predetermined angle range from a position above the opening end surface 61 of the ice making tray 60 to a position below the opening end surface 61. Specifically, the cold air passage 72 is formed at a portion facing one side of the ice tray 60. More specifically, the cold air passage 72 has an upper end at a position of about 17 degrees in a direction opposite to the rotation direction with the horizontal direction at 0 degrees, and a lower end at a position of about 30 degrees in the rotation direction, and has an arc shape. In the ice-making dish surrounding member 70, it is formed over the angle range of about 47 degrees.

Specifically, the cold air passage portion 72 is formed as a communication hole formed in the cold air induction portion 71. The communication hole is formed smaller than the size of the ice. More specifically, the cold air passage portion 72 is formed in a mesh shape that is inclined with respect to the longitudinal direction of the ice making tray enclosing member 70, and each communication hole is formed in a substantially parallelogram shape (or a rough diamond shape). . Moreover, some communication hole is formed in the outline triangular shape corresponded to a part of outline parallelogram shape.

By the way, in the refrigerator 1 which concerns on this embodiment, the ice-making apparatus 50 is arrange | positioned at the freezer compartment 20 side of the refrigerator 1, and the storage device 40 is arrange | positioned at the freezer compartment door 21 side. Therefore, when the user opens the freezer compartment door 21 while the ice making apparatus 50 is discharging the ice, a problem arises in which a situation in which the ice has been removed cannot be picked up by the ice storage apparatus 40 occurs. .

In order to solve this problem, the refrigerator 1 shortens the period (or time) in which ice is discharged from the ice making apparatus 50 as much as possible. Specifically, the extension part 73 is provided in the back side of the rotating direction in the ice-making dish surrounding member 70. As shown in FIG. This extension part 73 is a part which protruded in the radial direction (or the rotation direction) rather than the opening end surface 61 of the ice-making tray 60. FIG. In other words, the cold air storage portion is a portion corresponding to the extension portion 73.

Next, the ice-making operation of the ice making apparatus 50 which consists of said embodiment is demonstrated using FIG. 8 and FIG.

First, at the rotation angle of 0 degrees, the ice making tray 60 (opening end face 61 of the ice making tray) is horizontal. From that state, the ice tray 60 and the ice tray surrounding member 70 are rotated. Then, the ice tray 60 is rotated so that the inclined surface of the ice maker 64 is in close contact with the ice maker 64 from the viewpoint of the angular position (for example, the rotation angle of about 65 degrees). Ice does not begin to fall naturally by gravity. The ice dropped from the ice tray 60 is received by the extension 73 of the ice tray enclosure 70 and prevented from falling downward. In some cases, ice may be prevented from being caught by the ice tray enveloping member 70 and the ice detection lever 52. 8B and 9B are states at a rotation angle of 90 degrees. Also, about 9.5 seconds are required until the rotation angle is 90 degrees.

Then, the ice making tray 60 and the ice making tray surrounding member 70 are rotated to a rotation angle of 130 degrees shown in FIGS. 8C and 9C. In addition, it takes about 4.5 seconds from 90 degrees to 130 degrees of rotation angle. And the twisting operation of the ice tray 60 is started from the viewpoint of this rotation angle of 130 degree | times. Then, the ice tray 60 is deformed so that a force acts to push the ice out of the ice maker 64 to promote the ice. Further, from this point of time, the ice tray 60 begins to tilt forward, so that one end of the short side of the ice tray 60 starts to move in the right direction in FIG. 8, while the ice tray 60 is rotated to extend. The section 73 starts to move in the left direction in FIG. For this reason, it is reversed after the short side direction end part of the ice-making dish 60 and the extension part 73 are aligned in a perpendicular direction, and it becomes difficult to pick up the ice which fell from the ice-making dish 60 by the extension part. Therefore, the ice is discharged downward from the ice drop portion 51.

Thereafter, the ice tray 60 and the ice tray surrounding member 70 are rotated to a rotation angle of 160 degrees shown in FIGS. 8D and 9D. In addition, it takes about 3.5 seconds until the rotation angle reaches 130 degrees to 160 degrees. In addition, the twist degree of the ice-making tray 60 is set so that it may become the maximum at the time of the rotation angle of 160 degree | times.

Thus, by making the ice-making apparatus 50 with an ice fall prevention mechanism, it can prevent suitably that an ice falls out unpredictably in the period until the twisting operation of the ice-making pan 60 starts. That is, during the period in which the ice is not intended, the ice is held on the ice making machine 50 side by taking it out of the extension 73 of the ice making machine enveloping member 70, and then the twisting operation of the ice making machine 60 thereafter is performed. At the same time, ice is dropped onto the storage device 40 at once. Therefore, the period (or time) in which ice falls from the storage device 40 can be shortened, and the occurrence probability of the problem which may occur when the freezer compartment door 21 is opened during that time can be reduced.

In addition, even in the above configuration, if the freezer compartment door 21 is opened for about 3.5 seconds from the rotation angle of 130 degrees to 160 degrees, the problem of ice falling may still occur. For this reason, when the freezer compartment door 21 is open at least in the meantime, the rotation operation of the ice tray 60 and the ice tray surrounding member 70 and the twisting operation of the ice tray 60 are stopped. In addition, the notification means notifies the user that the moving is in progress. Specifically, a warning sound is generated, but this may be displayed on the display unit 11 (see FIG. 1) or the like.

In addition, the rotation operation of the ice tray 60 and the ice tray surrounding member 70, the twisting operation of the ice tray 60, the notice or display during the ice removal operation, and the like, not only after the start of the twist operation, but also the ice fall. It may be performed from the timing at which the angle is started, or may be performed from the rotation start time of the rotation operation of the ice making tray 60 and the ice making tray surrounding member 70.

As mentioned above, according to the refrigerator 1 and the ice-making apparatus 50 which concerns on this embodiment, while the ice can be manufactured quickly, the state of the ice stored in the storage device 40 can be maintained suitably.

That is, the ice making apparatus 50 which concerns on this embodiment is equipped with the cold air induction | conduction part 71 which guides the cold air which passed the upper direction of the ice-making pan 60 to the bottom part 62 side of the ice-making pan 60, The said cold air induction part The cold air passage part 72 which passes a part of cold air which passed above the ice-making dish 60 to the storage space 41 of the storage device 40 is formed in 71.

Therefore, when the freezer compartment 20 is opened, warm air enters from the outside, and the warm air touches the ice stored in the storage device 40 so that the surface of the ice melts, and the warm air further stores the storage space of the storage device 40. Even if it is in the state of staying in (41), a part of cold air is supplied to the storage space 41 of the storage device 40, and the air stayed in the storage space 41 can be cooled immediately, and the water of the surface of ice Can be frozen or evaporated immediately. Therefore, it is possible to appropriately prevent the plurality of ice from becoming frozen ice ingots.

In addition, the ice making dish 60 can be cooled from both sides of the opening end face 61 side and the bottom part 62 side by providing the ice making dish surrounding member 70. Therefore, the inside of the ice making space 81 can be cooled efficiently, and the ice making time can be shortened.

In addition, the refrigerator and ice-making apparatus which concerns on this invention are not limited to the structure of the said embodiment, A various change is possible within the range which does not deviate from the meaning of invention.

For example, as an ice fall prevention mechanism, the space | interval of the ice tray enclosing member 70 and the ice detection lever 52 is set so that it may become smaller than the size of ice, and the ice dropped from the ice tray 60 may be removed from the ice tray 52. It may be held between the ice tray enveloping members 70. Further, after a separate partition member is disposed between the ice tray enveloping member 70 and the ice detection lever 52, the space between the partition member and the ice tray enveloping member 70 is set to be smaller than the size of the ice to make the ice tray. The ice dropped from 60 may be held between the partition member and the ice tray enveloping member 70.

In the above embodiment, the refrigerator 1 of the type in which the freezer compartment 20 is closed by the freezer compartment door 21 connected by the hinge portion 24 has been described, but the present invention is not limited thereto. Naturally, the present invention can also be applied to a refrigerator having a drawer freezer.

In addition, in the said embodiment, although the cold air induction part 71 was demonstrated as being provided in the one end part of the ice-making dish surrounding member 70, it is not limited to this, The cold air induction part touches the cold air which passed above the ice-making dish. What is necessary is just to be arrange | positioned at the position, and what should just be able to guide the cold air which touched this cold air | air induction part to the downward side of an ice making pan. For example, the cold air induction part may be provided separately from the ice making machine enveloping member. In this case, the ice making machine enveloping member is rotatable while the cold air accommodating part can be considered to be fixed relative to the ice making machine housing in a non-displaceable manner. .

In addition, if the ice making apparatus which concerns on this invention can supply a part of cold air to the storage space 41 of the storage apparatus 40, it will not specifically limit the structure of the storage apparatus 40, For example, an ice storage part It is not necessary to supply cold air directly from the upper end opening portion. In this case, a duct or the like communicated with the storage space of the storage device may be separately provided.

In addition, in the said embodiment, although demonstrated as what arrange | positioned so that the upper end opening part 42 of the ice storage device 40 may be just under the ice drop part 51 of the ice-making device 50, the ice-making device 50 and the storage The positional relationship of the apparatus 40 is not limited to this, but the positional relationship of the ice storage apparatus 40 and the ice-making apparatus 50 does not become along a perpendicular direction, but the ice manufactured by the ice-making apparatus 50 is carried out. It may be guided to the device 40.

In addition, although the ice-making apparatus 50 was demonstrated as what is provided in the freezer compartment 20, it is not limited to this, It may be provided in the freezer compartment door 21 side. In this case, the structure which installs the ice-making device 50 directly above the storage device 40 can be considered, for example.

In addition, in the said embodiment, the ice-making apparatus 50 is realized by providing the storage space cooling mechanism and the extension part 73 of the storage device which are realized by forming the cold air passage part 72 in the cold air induction part 71. It demonstrated as having both sides of the fall prevention mechanism. In addition, the present invention has been described as having at least a storage space cooling mechanism. However, the ice-making apparatus in which only the said ice fall prevention mechanism is provided without a storage space cooling mechanism is also extractable as a technical idea of another invention.

1 is a perspective view showing a refrigerator provided with an ice maker according to an embodiment of the present invention.

Fig. 2 is a front view showing a state where the door of the refrigerator according to the embodiment is opened.

3 is a cross-sectional side view taken along the line A-A shown in FIG.

4 is a sectional perspective view of the ice making apparatus according to the embodiment;

Fig. 5 is a sectional side view of the ice making apparatus according to the embodiment.

Fig. 6 is a diagram showing an ice making apparatus according to the embodiment, and is a sectional plan view cut along the line B-B shown in Fig. 5;

7 is a perspective view of an ice making dish surrounding member of the ice making apparatus according to the embodiment;

Fig. 8 is a sectional side view showing an operating state of the ice making apparatus according to the above embodiment, wherein (A) is a rotation angle of 0 degrees, (B) is a rotation angle of 90 degrees, (C) is a rotation angle of 130 degrees, and (D) Is a figure which shows the state of rotation angle 160 degree.

Fig. 9 is a sectional perspective view showing an operating state of the ice making apparatus according to the embodiment, wherein (A) is a rotation angle of 0 degrees, (B) is a rotation angle of 90 degrees, (C) is a rotation angle of 130 degrees, and (D) Is a diagram showing a state of rotation angle 160.

<Explanation of symbols for the main parts of the drawings>

1: refrigerator

10: dispenser unit

11: display unit

20: first storage compartment (freezing compartment)

21: freezer door

22: cooling fan

23: duct

24: hinge part

30: second storage room

32: refrigerator

33: Vegetable Room

34: refrigerator door

35: vegetable room door

36: water tank

4O: Saving Device

41: storage space

42: upper opening

50: ice making device

51: ice drop

52: detection lever

60: ice tray

61: opening end surface

62: bottom

63: compartment

64: ice making unit

70: ice tray encircling member

71: cold air induction part

72: cold air passage

73: extension part

80: ice maker housing

81: ice making space

82: feed pipe insertion part

83: cold air intake

84: cold air outlet

90 drive unit

Claims (5)

A storage device installed at the inner side of the door to store ice in the storage space; An ice making device disposed above the storage device, The ice making device, An ice making dish having a bottom and an opening end face; An arc-shaped ice tray enclosing member provided with a cold air induction part for guiding the cold air that has passed above the ice tray to the bottom side of the ice tray; The said ice-making apparatus flows cold air along the said opening end surface of the said ice-making pan, and flows the cold air which passed above the ice-making pan to the bottom side of the ice-making pan, and flows along the bottom, and the flow of cold air surrounds an ice-making pan. Is configured to The cold air induction part is provided with a cold air passing part for passing a portion of the cold air that has passed above the ice making tray to the storage space of the storage device, An extension part is provided in the said ice tray enveloping member, The said extension part receives the ice which fell when the said ice tray rotated to a predetermined angle, And the extension portion is aligned in a vertical direction with one end of the short side direction of the ice tray when the ice tray is further rotated, thereby dropping ice onto the ice storage device. The ice making apparatus according to claim 1, wherein the cold air passage portion is formed as a through hole formed in the cold air induction portion. The said ice-making dish is rotationally driven so that the said opening end surface may face downward and is comprised so that ice may fall from this opening end surface downward, The ice making machine enveloping member is configured to rotate integrally with the rotation of the ice making machine. A refrigerator comprising the ice making device according to claim 1. delete

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