KR101632213B1 - A refrigerator and an ice bank - Google Patents

Abstract

The present invention relates to a refrigerator that can easily and accurately couple a blade of an ice bank or a rotation axis of an auger to a rotation axis of a motor that rotates the ice bank when the user mounts the ice bank in the refrigerator.

The refrigerator of the present invention comprises: an ice bank for storing ice that has been ice-removed from an ice-maker; An ice discharge member rotatably provided in the ice bank and discharging ice; A motor unit selectively connected to the ice discharge member to rotate the ice discharge member; And the driving force of the driving shaft is transmitted to the rotating shaft of the ice discharge member and the driving force of the driving shaft is transmitted to the rotating shaft of the ice discharge member between the driving shaft and the rotating shaft, And a joint part for converting the connection relationship in which the driving force is not transmitted to the connection relationship in which the driving force is transmitted when the motor is driven,

Refrigerator, Ice maker, Ice bank, Joint, Rotary shaft, Motor

Description

A REFRIGERATOR AND AN ICE BANK < RTI ID = 0.0 >

The present invention relates to a refrigerator and an ice bank that can easily and accurately couple a blade of an ice bank or a rotation axis of an auger to a rotation axis of a motor that rotates the ice bank when the user mounts the ice bank in the refrigerator.

A refrigerator is a household appliance that can store refrigerated or frozen food by using refrigerant cycles of compression, condensation, expansion, and evaporation.

The main structure of the refrigerator includes a main body having a storage chamber, a door installed in the main body for opening and closing the main body, and an ice maker provided in the storage room or the door.

The storage room or the door is provided with an ice bank for storing ice discharged from the ice maker. The ice bank is connected to a dispenser for taking out the ice, so that the ice can be discharged to the outside according to the user's choice.

Generally, the ice bank is coupled to the bottom of the ice maker. An ice transfer device for transferring the stored ice to the dispenser is installed in the ice bank. The ice transfer device has a rotation shaft connected to the motor for automatically transferring ice to the dispenser when a user presses a button provided on the outside of the dispenser. This rotary shaft is connected to the drive shaft of the motor provided at the rear side of the ice bank and rotated by the rotation of the motor.

Such an ice bank should be easily detachable by the user for cleaning the interior or the like.

However, in the conventional ice bank, when the rotation axis of the ice bank is not mounted in a proper position in the process of shaft coupling with the drive shaft of the motor, normal operation can not be performed. In addition, when the contact surface of the joint is formed as an inclined surface, mounting can be facilitated somewhat, but power transmission is not properly performed when the rotary shaft has to be rotated in the forward and reverse directions. This has resulted in lowering the reliability of the refrigerator and the inconvenience of using the refrigerator.

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an ice bank in which even when the rotation axis of the ice bank and the drive shaft of the motor are not mounted at an accurate angle, And a refrigerator having the same.

According to an aspect of the present invention, there is provided a refrigerator including: an ice bank for storing ice cubes; An ice discharge member rotatably provided in the ice bank and discharging ice; A motor unit selectively connected to the ice discharge member to rotate the ice discharge member; And the driving force of the driving shaft is transmitted to the rotating shaft of the ice discharge member and the driving force of the driving shaft is transmitted to the rotating shaft of the ice discharge member between the driving shaft and the rotating shaft, And a joint part for converting the connection relationship in which the driving force is not transmitted to the connection relationship in which the driving force is transmitted when the motor is driven,

The joint portion may include a motor joint axially coupled to an end portion of the drive shaft of the motor portion; And a bank joint which is mounted so as to face the motor joint and is axially coupled to an end portion of the rotation shaft of the ice discharge member.

The bank joint may include a connecting plate slidably mounted on an end portion of the rotation shaft of the ice discharge member and selectively connected to the motor joint; A support plate installed on the rotation axis of the ice discharge member at a predetermined interval from the connection plate; And an elastic member provided between the connection plate and the support plate to push the connection plate in the axial direction.

The bank joint may further include a rotating plate rotatably provided in a recess formed at the center of the support plate.

Preferably, the connection plate is supported by a head integrally formed on an end portion of the rotation shaft of the ice discharge member so as to be prevented from being separated from the rotation shaft.

Further, the motor joint includes: a center portion having a shaft hole formed at the center of the rectangular plate; And a bent portion formed at both ends of the plate so as to be axially bent.

Preferably, the connection plate includes a protrusion contacting the side surface of the bending portion of the motor joint and transmitting the rotation force of the motor to the rotation axis of the ice discharge member.

The connection plate may further include a guide portion formed to be axially bent along a circumferential end edge and connected to the protrusion.

In addition, it is preferable that the rotation axis of the ice discharge member is chamfered so that both sides thereof are parallel to each other, and the connection plate and the rotation plate are each formed with a rectangular shaft hole so that the rotation axis is inserted.

Preferably, the drive shaft of the motor unit is chamfered so that both sides thereof are parallel to each other, and the motor joint is formed with a rectangular shaft hole for inserting the drive shaft.

The ice bank according to the present invention comprises: an ice discharge member which is rotatably provided inside the ice bank and discharges ice; A motor unit selectively connected to the ice discharge member to rotate the ice discharge member; And the driving force of the driving shaft is transmitted to the rotating shaft of the ice discharge member and the driving force of the driving shaft is transmitted to the rotating shaft of the ice discharge member between the driving shaft and the rotating shaft, And a joint part for converting the connection relationship in which the driving force is not transmitted to the connection relationship in which the driving force is transmitted when the motor is driven,

The joint portion may include a motor joint axially coupled to an end portion of the drive shaft of the motor portion; And a bank joint which is mounted so as to face the motor joint and is axially coupled to an end portion of the rotation shaft of the ice discharge member.

The bank joint may include a connecting plate slidably mounted on an end portion of the rotation shaft of the ice discharge member and selectively connected to the motor joint; A support plate installed on the rotation axis of the ice discharge member at a predetermined interval from the connection plate; And an elastic member provided between the connection plate and the support plate to push the connection plate in the axial direction.

The bank joint may further include a rotating plate rotatably provided in a recess formed at the center of the support plate.

Preferably, the connection plate is supported by a head integrally formed on an end portion of the rotation shaft of the ice discharge member so as to be prevented from being separated from the rotation shaft.

Further, the motor joint includes: a center portion having a shaft hole formed at the center of the rectangular plate; And a bent portion formed at both ends of the plate so as to be axially bent.

Preferably, the connection plate includes a protrusion contacting the side surface of the bending portion of the motor joint and transmitting the rotation force of the motor to the rotation axis of the ice discharge member.

The connection plate may further include a guide portion formed to be axially bent along a circumferential end edge and connected to the protrusion.

According to the refrigerator of the present invention, even when a driving force of the driving shaft is not transmitted to the rotation axis of the ice discharge member when the rotation axis of the ice bank is connected to the driving shaft of the motor, It is possible to convert the driving force into a connecting relationship in which the driving force is transmitted by the actuation so that accurate axial coupling can be achieved.

In addition, even when the rotation axis of the ice bank is rotated not only in the normal direction but also in the reverse direction, it is possible to precisely join the joints so that interference does not occur between the joints.

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

1, a refrigerator according to the present invention includes a main body 1 having a storage room 5, a door 10 rotatably installed on the main body 1 to open and close the storage room 5, .

An ice making chamber 20 is provided inside the door 10 and an ice maker 30 for ice making ice is disposed inside the ice making chamber 20 and ice made by the ice maker 30 is stored in a dispenser And an ice bank 200 for discharging the ice bank 200 (not shown).

In the meantime, a motor unit 100 for driving the ice discharge member provided in the ice bank 200 is provided at the rear of the ice bank 200.

An ice making chamber door 21 is provided at one side of the ice making chamber 20 to selectively open and close the ice making chamber 20.

2 is a perspective view showing the ice-maker 30, the ice bank 200, and the motor unit 100 separated from each other in the refrigerator of FIG.

The ice maker 30, the ice bank 200, and the motor unit 100 are mounted on the mounting plate 150 and detachably mounted in the ice making chamber 20 of the refrigerator. The icemaker (30) is mounted on the front upper portion of the mounting plate (150), and the ice bank (200) is mounted thereunder. The motor unit 100 is mounted so that a motor (see FIG. 5) 110 is received in the receiving portion 250 recessed at the rear of the mounting plate 150. 2, the motor 110 coupled to the power transmission unit 115 of the motor unit 100 is omitted.

The drive shaft 120 of the motor unit 100 is axially coupled to a rotary shaft (see FIG. 3, 310) of the ice bank 200 through a shaft hole 151 formed in the mounting plate 150 by a joint portion .

As described above, the refrigerator according to the present invention includes an ice bank 200 for storing ice that has been dispensed from the ice maker 30; An ice discharge member rotatably installed in the ice bank 200 to discharge ice; A motor unit 100 selectively connected to the ice discharge member to rotate the ice discharge member; The ice discharge member is provided between the end of the rotation shaft 310 of the ice discharge member and the drive shaft 120 of the motor unit 100 to transmit the drive force of the drive shaft 120 to the rotation shaft 310 of the ice discharge member, And a joint part for converting a connection relationship in which a driving force is not transmitted to a connection relationship in which a driving force is transmitted when the motor is driven when a driving force of the driving shaft is not transmitted to the rotation axis of the ice discharge member between the rotation shafts .

The joint unit includes a motor joint 130 axially coupled to an end of the driving shaft 120 of the motor unit 100; And a bank joint that is mounted to face the motor joint 130 and is axially coupled to an end of the rotation shaft 310 of the ice discharge member.

The bank joint may include a connection plate 320 slidably mounted on an end portion of the rotation shaft 310 of the ice discharge member and selectively connected to the motor joint; A support plate 340 installed on the rotation axis 310 of the ice discharge member at a predetermined interval from the connection plate 320; And an elastic member 330 provided between the connection plate 320 and the support plate 340 to push the connection plate 320 in the axial direction.

The bank joint may further include a rotation plate 345 rotatably provided in a recess formed in the center of the support plate 340.

First, the structure of an ice bank to which the present invention can be applied will be described with reference to FIGS. 3 and 4. FIG.

3, the outer case of the ice bank 200 includes a rear member 210 having an ice discharging member installed therein, and a front member 210 having a transparent material coupled to a front opening surface of the rear member 210. [ (220) and a cover member (230) coupled to cover the lower half of the front member (220).

A joint mounting hole 215 in which a connecting plate 320 and a support plate 340 to be described later are rotatably installed is formed at a lower portion of the rear member 210. The diameter of the joint mounting hole 215 is smaller than the diameter of the support plate 340 although the connection plate 320 is inserted and rotatable. 3 and 6, it will be understood that the support plate 340 is fixed so as not to move in the axial direction by the inner wall surface of the rear member 210 and the rotating blade portion 350 described later.

4 is a view showing the assembly of the components of the ice discharge member installed in the ice bank 200 in the order of assembly. The connecting plate 320, the elastic member 330, the supporting plate 340 and the rotating blade 350 are inserted into the rotary shaft 310 in order and the screws 370 are screwed into the screw holes 318 formed in the end surface of the rotary shaft. As shown in Fig.

The rotating blade unit 350 includes a plurality of blades 354 and a gap holding member 356 that maintains a constant gap between the blades. The blade 354 has three blades extended, but two or four blades may be used. The number of blades is not limited to three, and two to six blades may be formed.

3, both ends of the fixed blade 360 are inserted between the blades 354 of the rotary blade 350 at the lower ends of the rotary shaft 310 and the rear member 210, respectively, .

The discharge port of the discharge portion formed below the ice bank 200 together with the rotating blade portion 350 may be selectively disposed on the opposite side of the same height as the stationary blade portion 360 with the rotating blade portion 350 interposed therebetween. And an opening / closing member 500 for opening and closing and discharging the ice below is disposed.

The opening and closing member 500 is rotatably disposed on the discharge portion and is preferably made of an elastic material or supported by an elastic member 540 such as a spring. This is to allow the end portion to move downward due to the pressing action by the ice, and to return to the original position when the pressing action by the ice is released.

In the illustrated embodiment, the ice discharging member uses a plurality of blades to break down the ice that enters between the fixed blade 360 and the rotating blade 350 by rotating relative to the fixed blade 360 and the rotating blade 350, Let them fall into the dispenser. When the rotating blade portion 350 is rotated in the reverse direction, the cylinder ice is discharged without being crushed.
That is, the ice discharge member includes a rotating shaft 310 rotated by the motor unit 100, a rotating blade unit 350 mounted on the rotating shaft 310 and rotating together with the rotating shaft 310, And a stationary blade unit 360 mounted between the inner side surfaces of the ice bank 200 to crush ice therebetween as the rotating blades rotate.

However, the present invention is not limited to the one in which the ice discharge member is made of only a plurality of blades. That is, an auger may be mounted at a position where the rotating blade unit 350 is mounted, which functions to feed the ice downward without crushing the ice. Also, the rotation shaft 310 may be longer than the rotation blade 350, and an ice transfer member such as an auger may be mounted thereon.

The rotation shaft 310 includes a first shaft portion 314 through which the connection plate 320 is inserted and slid and a second shaft portion 316 installed to prevent the support plate 340 and the rotating blade portion 350 from being inserted ). The first shaft portion 314 is preferably slightly larger in diameter than the second shaft portion 316. The head 312 is integrally formed at the end of the first shaft portion 314 so that even if the elastic member 330 pushes the connecting plate 320 in the end direction of the first shaft portion 314, And is prevented from being detached from the rotary shaft 310.

The connecting plate 320 is formed in a disk shape as a whole, and a shaft hole 322 into which the first shaft portion 314 is inserted is formed at the center. A triangular protrusion 324 protrudes axially on both sides of the shaft hole 322 of the connecting plate 320. The projecting portion 324 contacts the side surface of the bent portion 136 of the motor joint 130 to be described later to transmit the rotation force of the motor to the rotation axis 310 of the ice discharge member.

Further, a guide portion 326 is formed in an axial direction on the circumferential end edge of the connecting plate 320. 5) of the motor joint 130 to be described later is inserted, the guide portion 326 is engaged with the rotation shaft 310 of the ice bank 200 and the motor portion 100 And serves to guide the drive shaft 120 to rotate on the same straight line.

Next, the support plate 340 is fixedly installed on one side of the rotary blade 350 and the inner side surfaces of the rear mounting member 215 around the joint mounting hole 215. It is preferable that a recess is formed at the center of the support plate 340 so as to allow the rotation plate 345 to be rotatably inserted therein, as best shown in Fig. A rectangular shaft hole 342 is formed in the center of the rotary plate 345 so that the first shaft portion 314 of the rotary shaft 310 is inserted and rotated together with the rotary shaft 310.

In addition, a projection insertion portion 347 in the form of a recess extending toward the rear member 210 is formed at the peripheral end edge of the support plate 340. A circular protrusion 212 protruding from the inner surface of the rear member 210 about the rotation axis 310 is inserted into the protrusion insertion portion 347 to support the support plate 340.

Accordingly, when the rotation shaft 310 rotates, the rotation plate 345 rotates along the rotation axis. However, the support plate 340 is supported by the circular protrusion 212 formed on the inner wall surface of the rear member 210, and is maintained in a fixed state without being rotated.

In addition, the outer surface of the support plate 340 where the protrusion inserting portion 347 is formed is formed as an inclined surface, so that the ice contained in the ice bank 200 is prevented from falling down due to its own weight.

The elastic member 330 is installed between the support plate 340 and the connection plate 320. The elastic member 330 is preferably a compression spring in the form of a spring. The elastic member 330 pushes the connection plate 320 toward the head 312 of the rotation shaft 310 because the support plate 340 is fixed on the rotation axis 310 in the axial direction.

The first shaft portion 314 of the rotation shaft 310 is inserted into the center of the elastic member 330. When the rotation shaft is rotated, the rotation plate 345 and the connection plate 320 are rotated together, The elastic member 330 is also rotated.

5 is a perspective view showing that the rotation axis 310 of the ice bank 200 and the drive shaft 120 of the motor unit 100 are coupled by the joint portion.

The motor 110 is mounted on the power transmission unit 115 and the drive shaft 120 is rotatably protruded from the side surface of the power transmission unit 115 at a predetermined distance from the motor 110 have. Generally, a plurality of gears are combined with the power transmitting portion 115 to transmit the rotational force to the drive shaft 120 by reducing the rotational speed of the motor 110, but may be connected by a belt or the like. When the motor unit 100 is coupled to the ice bank 200, the motor 110 is housed in the motor housing unit 250, so that the rotation shaft of the motor 110 is connected to the ice bank 200, And does not coincide with the rotation axis 310. Accordingly, the rotational force of the motor 110 is transmitted to the driving shaft 120, which is coupled to the driving shaft 120 so as to be positioned on the same line as the rotating shaft 310 of the ice bank through the power transmitting unit 115. Therefore, the drive shaft 120 should be designed so that the center of the drive shaft 120 can coincide with the rotational axis 310 of the ice bank 200 so as to be axially coupled.

The driving shaft 120 of the motor unit 100 is installed on the side of the power transmission unit 115 so as to protrude from the side surface of the power transmission unit 115. A motor joint 130 is inserted into the drive shaft 120 through a rectangular shaft hole 134 formed at the center of the motor shaft 130 and a screw 140 is screwed into a screw hole 124 formed at an end of the drive shaft 120, 130 are coupled to rotate together with the drive shaft 120. The driving shaft 120 is inserted into the driving shaft 120 so as to coincide with the rectangular shaft hole 134 formed in the motor joint 130, To the motor joint 130 as it is. It is preferable that the length of the chamfered portion 122 coincides with the thickness of the motor joint 130 so that the motor joint 130 does not move in the axial direction while being inserted into the drive shaft 120. [

The motor joint 130 has a rectangular shaft hole 134 formed at the center of the center portion 132 of the plate shape and a bent portion 136 bent perpendicularly to both sides of the shaft hole 134. When the motor joint 130 is pushed into the connecting plate 320, the bent portion 136 rotates the connecting plate 320 while being in contact with the side surface of the protruding portion 324 of the connecting plate 320. Therefore, when the motor joint 130 rotates, one side surface of one of the both bent portions 136 and the side surface opposite to the diagonal line of the side surfaces of the both side bent portions 136 are simultaneously pressed on the side surface in the same rotational direction of both protruding portions 324 of the connecting plate 320 .

6 and 7 are partial cutaway perspective views showing a state in which the motor joint 130 is mounted on the connecting plate 320 with the joint mounting hole 215 formed in the rear member 210 of the ice bank 200 as a center. 6 is a view showing a state in which the motor joint 130 of the motor unit 100 is completely inserted into the connecting plate 320 to complete the shaft coupling. (See FIG. 6 and 7, the power transmission unit 115 and the drive shaft 120 of the motor unit 100 are not shown, and only the motor joint 130 and the screw 140 are shown.

When the motor joint 130 is coupled to the connecting plate 320, the bent portion 136 may not contact the protruding portion 324. [ 6, the bending portion 136 of the motor joint 130 is supported by the inner side surface of the guide portion 326 of the connecting plate 320, and the bending portion 136 of the motor joint 130 is supported by the protrusions 324 within a limited angular range The motor joint 130 can be rotated. In this case, the elastic member 330 pushes the connection plate 320 toward the head portion 312 of the rotation shaft 310.

When the driving shaft 120 and the motor joint 130 are rotated by driving the motor 110, the coupling plate 320 is rotated while pushing the protrusions 324 of the coupling plate 320. Accordingly, the rotation shaft 130 inserted in the shaft hole 322 of the connection plate 320 is rotated, and the rotation plate 345 mounted on the support plate is also rotated. At this time, the resilient member, that is, the spring 330 inserted between the rotating plate 345 and the connecting plate 320 also rotates naturally. On the other hand, the support plate 340 rotates only the rotation plate 345 in its center concave portion, but does not rotate together but supports the rotation plate 345.

7, when the bent portion 136 of the motor joint 130 is caught by the protruding portion 324 of the connecting plate 320 when the connecting plate 320 and the motor joint 130 are coupled to each other, The motor joint 130 pushes the connecting plate 320 in. The maximum distance that the connecting plate 320 slides on the rotating shaft 310 and reaches the maximum distance corresponds to the distance between the supporting plate 340 and the connecting plate 320 facing each other. When the connecting plate 320 is pushed in, the spring 330 between the connecting plate 320 and the rotating plate 345 is compressed. When the motor 110 is started in this state, the motor joint 130 rotates at a predetermined angle, and the bent portion 136 is rotated to a position where the protruding portion 324 is absent. When the compressed spring 330 pushes the connecting plate 320 toward the head portion 312 of the rotating shaft 310, the motor joint 130 is positioned on the connecting plate 320 as shown in FIG. 6 will be.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Changes will be possible.

1 is a view showing an ice-maker and an ice bank mounted in a refrigerator according to the present invention.

2 is a perspective view showing the ice maker, the ice bank, and the motor unit separated from each other in the refrigerator of FIG.

3 is an exploded perspective view showing the inside of the ice bank.

4 is an exploded perspective view of parts mounted on the rotating shaft inside the ice bank.

5 is an exploded perspective view showing that the rotation axis of the ice bank and the drive shaft of the motor unit are coupled by the joint portion.

6 is a partially cutaway perspective view showing the vicinity of the end portion of the rotating shaft of the ice bank.

FIG. 7 is a partially cutaway perspective view showing a state in which the motor joint in the joint portion of FIG. 6 pushes the projecting portion of the connecting plate.

Description of the Related Art

1: Refrigerator body

100:

120: drive shaft

130: Motor joint

140: Screw

200: Ice Bank

210: rear member

215: Joint mounting ball

220: front member

225: Rotating shaft mounting hole

250: motor receiving portion

delete

310:

320: connection plate

330: elastic member

340: Support plate

345: Spindle

350: rotating blade part
360: fixed blade portion

Claims (20)

An ice bank for storing ice that has been ice-removed from the ice-making machine; An ice discharge member rotatably provided in the ice bank and discharging ice; A motor unit selectively connected to the ice discharge member to rotate the ice discharge member; A motor joint shaft-coupled to the drive shaft of the motor unit and rotating together; And And a bank joint mounted on a rotary shaft of the ice discharge member and coupled to the motor joint to transmit a driving force of the motor to the ice discharge member, The bank joint includes: A connection plate slidably mounted on the rotation shaft of the ice discharge member in an axial direction and rotated in contact with the motor joint, A support plate disposed on the rotation axis of the ice discharge member at a predetermined interval from the connection plate, And an elastic member provided between the connection plate and the support plate to provide an elastic force to push the connection plate in the axial direction when the connection plate is pushed and moved by the motor joint when the motor joint and the bank joint are engaged, . delete The method according to claim 1, Wherein the bank joint further comprises a rotating plate rotatably mounted on a recess formed at the center of the support plate and rotated together with the rotation axis. The method of claim 3, Wherein the connection plate is supported by a head integrally formed at an end portion of the rotation shaft of the ice discharge member to prevent the rotation from being separated from the rotation shaft. The method of claim 3, Wherein the motor joint comprises: A center portion having a shaft hole formed at the center of the rectangular plate; And a bent portion formed at both ends of the plate so as to be axially bent. 6. The method of claim 5, Wherein the connecting plate includes a protrusion for contacting the bending portion side surface of the motor joint and transmitting rotation force of the motor to the rotation axis of the ice discharge member. The method according to claim 6, Wherein the connecting plate further includes a guide portion formed to be axially bent along a circumferential end edge and connected to the protrusion. The method according to claim 6, The rotation axis of the ice discharge member is chamfered so that both side surfaces thereof are parallel to each other, Wherein the connecting plate and the rotating plate are each formed with a rectangular shaft hole for inserting the rotating shaft. 6. The method of claim 5, Wherein a driving shaft of the motor unit is chamfered such that both side surfaces thereof are parallel to each other, Wherein the motor joint is formed with a rectangular shaft hole for inserting the drive shaft. 10. The method of claim 9, Wherein the motor joint is fastened to the end of the driving shaft of the motor unit using a screw. 1. An ice bank for storing iced ice in an icemaker, An ice discharge member rotatably provided in the ice bank and discharging ice; A motor unit selectively connected to the ice discharge member to rotate the ice discharge member; A motor joint shaft-coupled to the drive shaft of the motor unit and rotating together; And And a bank joint mounted on a rotary shaft of the ice discharge member and coupled to the motor joint to transmit a driving force of the motor to the ice discharge member, The bank joint includes: A connection plate slidably mounted on the rotation shaft of the ice discharge member in an axial direction and rotated in contact with the motor joint, A support plate disposed on the rotation axis of the ice discharge member at a predetermined interval from the connection plate, And an elastic member provided between the connection plate and the support plate to provide an elastic force to push the connection plate in the axial direction when the connection plate is pushed and moved by the motor joint when the motor joint and the bank joint are engaged, Ice bank. delete 12. The method of claim 11, Wherein the bank joint further comprises a rotation plate rotatably mounted on a recess formed at the center of the support plate and rotated together with the rotation axis. 12. The method of claim 11, Wherein the connection plate is supported by a head integrally formed at an end portion of the rotation shaft of the ice discharge member to prevent the rotation from being separated from the rotation shaft. 12. The method of claim 11, Wherein the motor joint comprises: A center portion having a shaft hole formed at the center of the rectangular plate; And bending portions formed at both ends of the plate in the axial direction. 16. The method of claim 15, Wherein the connection plate includes a protrusion that contacts the side surface of the bent portion of the motor joint and transmits rotation force of the motor to the rotation axis of the ice discharge member. 17. The method of claim 16, Wherein the connecting plate further includes a guide portion formed to be axially bent along a circumferential end edge and connected to the protrusion. 17. The method of claim 16, The rotation axis of the ice discharge member is chamfered so that both side surfaces thereof are parallel to each other, Wherein the connecting plate and the rotating plate are each formed with a rectangular shaft hole for inserting the rotating shaft. delete delete

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