KR101177462B1 - A ice storage device and A refrigerator including thereof and A water purifier including thereof - Google Patents

Abstract

The present invention relates to an ice storage device and a refrigerator and a water purifier including the same, and more particularly, to an ice that is stored in a state of being discharged in ice or crushed state, and discharged through various routes. .
Ice storage; A plurality of ice discharge ports provided in the ice storage box; An ice transfer member provided in the ice storage box and selectively moving the ice to the plurality of ice discharge ports; A rotational opening / closing member provided on one side of the ice conveying member to alternately block the discharge path of the ice communicating with at least one of the plurality of ice outlets according to the rotation of the ice conveying member; It relates to a refrigerator and a water purifier comprising an ice crushing device comprising an ice crushing device provided adjacent to the rotary opening and closing member to crush the ice passing through the rotary opening and closing member. .

Description

A ice storage device and a refrigerator, including a refrigerator and a water purifier including the same

The present invention relates to an ice storage device and a refrigerator and a water purifier including the same, and in detail, an ice storage device which can be discharged through various routes while being discharged in ice or crushed state. It relates to a refrigerator and a water purifier including the same.

The refrigerator or the water purifier for supplying ice is provided with an ice making device, an ice storage container for storing the ice iced by the ice making device, and an ice transporting device provided inside the ice storage box and transferring the ice to discharge the ice to the outside.

The conventional ice storage device includes an ice storage container having a predetermined space, an ice transfer member provided inside the ice storage box, and an ice discharge port provided on one side of the ice storage box.

Thus, when the discharge of ice is necessary, the ice transfer member operates to transfer the ice to the ice discharge member. As such, the ice moved by the ice discharge member is discharged to the outside through a dispenser provided in the refrigerator or the water purifier.

By the way, in the prior art, the ice collected in the ice container was discharged only in one direction.

The necessity of discharging ice in multiple directions simultaneously or selectively for use in various purposes, for example, for forming edible ice and cooling drinking water by ice, without discharging the ice in the ice container outside the refrigerator or water purifier. .

However, there has been a problem that the conventional technology in which ice is taken out only in one direction cannot satisfy such a necessity.

The present invention has been made to solve the above problems, and an object thereof is to provide an ice storage device, a refrigerator including the same, and a water purifier in which ice can be taken out in various directions.

It is another object of the present invention to provide an ice storage device, a refrigerator including the same, and a water purifier in which crushed ice and uncrushed ice can move to various routes.

The present invention for achieving this object is ice storage; A plurality of ice discharge ports provided in the ice storage box; An ice transfer member provided in the ice storage box and selectively moving the ice to the plurality of ice discharge ports; A rotational opening / closing member provided on one side of the ice conveying member to alternately block the discharge path of the ice communicating with at least one of the plurality of ice outlets according to the rotation of the ice conveying member; It is provided adjacent to the rotary opening and closing member provides an ice storage device comprising an ice crushing device is provided to crush the ice passing through the rotary opening and closing member.

The plurality of ice discharge port is the first ice discharge port provided on one side of the ice container; And a second ice discharge port provided on the other side of the ice container, wherein the ice crushing device is provided adjacent to the first ice discharge port.

The first ice discharge outlet is provided on the opposite side of the second ice discharge outlet.

The ice transfer member is provided to enable forward rotation and reverse rotation,

A rotating shaft; It characterized in that it comprises a conveying portion provided on the rotating shaft and composed of a spiral blade.

The ice grinding device includes a housing portion provided adjacent to the first ice discharge port;

A rotary cutter unit accommodated in the housing part and provided at one end of the rotary shaft and configured to rotate according to the rotation of the rotary shaft;

It is fixed to the housing portion characterized in that it comprises a fixed cutter unit for crushing the ice with the rotary cutter unit when the rotary cutter unit rotates.

One side of the rotary opening and closing member is open, the other side is composed of a hollow member that is partially open, the rotary opening and closing member is provided with a blocking wall portion provided on the other side; It is provided adjacent to the blocking wall portion characterized in that it comprises an opening provided to pass the ice.

An ice inlet provided at one side of a housing part of the ice grinding device and communicating with the opening part; It is characterized in that it comprises an ice outlet for discharging the crushed ice provided on the lower side of the housing portion of the ice crushing device.

The rotary cutter units are spaced apart from each other, but are disposed in a sequential order and include a plurality of rotary cutters having different phase angles, and the fixed cutter unit is disposed between the rotary cutters so that the plurality of rotary cutters can pass therethrough. It is characterized by.

The fixed cutter unit includes a plurality of fixed cutters disposed between the plurality of rotary cutters; An ice seat portion provided in the fixed cutter and having an opening shape in which ice has passed through the opening portion; It is characterized in that it comprises a cutter unit which is provided inside the ice seating portion to crush the ice with the cutter portion provided in the rotary cutter.

The fixed cutter has a shape corresponding to the shape of the opening of the rotary opening and closing member.

It is formed so as to protrude on the bottom surface of the ice container, characterized in that it further comprises a guide protrusion for guiding to move into the rotary opening and closing member while preventing the ice moving by the transfer portion to the body edge of the rotary opening and closing member. do.

It characterized in that it further comprises an opening and closing unit for opening and closing the second ice discharge port.

The opening and closing unit is provided on the rotating shaft rotatably and opening and closing the opening and closing the second ice discharge port; A protrusion protruding from an outer circumferential surface of the rotating shaft; And a friction member provided between the protrusion and the opening and closing member and in surface contact with the protrusion and the opening and closing member to transmit rotational force according to the rotation of the rotation shaft to the opening and closing member.

The opening and closing unit is provided on the rotating shaft rotatably and opening and closing the opening and closing the second ice discharge port; A rotating shaft gear part provided on an outer circumferential surface of the rotating shaft; And a transmission gear part engaged with the rotary shaft gear part and engaged with the opening / closing member gear part provided in the opening / closing member to transmit the power of the rotary shaft gear part to the opening / closing member.

The present invention also ice storage; A first ice discharge outlet provided in the ice container and a second ice discharge outlet disposed in a direction opposite to the first ice discharge outlet; The ice container is provided so as to be rotated forward and backward, the ice conveying member for selectively moving the ice to the first ice discharge port or the second ice discharge port, and provided on one side of the ice conveying member according to the rotation of the ice conveying member A rotation opening and closing member for alternately blocking the movement of the ice moving to the ice discharge port; An opening / closing unit connected to the ice conveying member and provided on the opposite side of the rotating opening and closing member to open and close the second ice discharge port; It is provided adjacent to the first ice discharge port and the rotary opening and closing member to provide a refrigerator having an ice storage device, characterized in that it is provided to crush and discharge the ice passing through the rotary opening and closing member. do.

In addition, the present invention ice storage; A first ice discharge outlet provided in the ice container and a second ice discharge outlet disposed in a direction opposite to the first ice discharge outlet; The ice container is provided so as to be rotated forward and backward, the ice conveying member for selectively moving the ice to the first ice discharge port or the second ice discharge port, and provided on one side of the ice conveying member according to the rotation of the ice conveying member A rotation opening and closing member for alternately blocking the movement of the ice moving to the ice discharge port; An opening / closing unit connected to the ice conveying member and provided on the opposite side of the rotating opening and closing member to open and close the second ice discharge port; It is provided adjacent to the first ice discharge port and the rotary opening and closing member provides a water purifier having an ice storage device, characterized in that it comprises an ice crushing device is provided to crush and discharge the ice passing through the rotary opening and closing member. do.

According to the present invention, the ice transfer member can move the ice in different directions while the forward or reverse rotation, and the ice moved in the different directions are discharged in the ice state, or crushed ice Can be discharged.

Thus, when the route to be discharged in the form of ice and the route to be discharged in the form of ice is different, the stored ice can be moved to meet different purposes. There is an advantage that the convenience can be improved.

Figure 1 is a side cross-sectional view showing that the ice storage device according to the present invention is installed.
Figure 2 is a perspective view showing that the ice storage device according to the present invention is installed.
Figure 3 is a side cross-sectional view of the ice storage device according to the present invention.
Figure 4 is a perspective view of the ice transfer member and the rotary opening and closing member and the ice crushing apparatus according to the present invention.
5 (a) and 5 (b) show a first embodiment of an opening and closing device for opening and closing a second ice discharge port in an ice storage device according to the present invention.
6 (a) and 6 (b) show a second embodiment of the switchgear for opening and closing the second ice discharge port in the ice storage device according to the present invention.
7 (a) and 7 (b) show a third embodiment of the opening and closing device for opening and closing the second ice discharge port in the ice storage device according to the present invention.
8 is a side view showing the ice is discharged to the first ice discharge port after the ice is crushed by the ice crushing device in the ice storage device according to the present invention.
Figure 9 is a front view showing that the ice is crushed by the ice grinding device in the ice storage device according to the present invention.
Figure 10 is a side view showing that the ice is discharged to the second ice discharge port in the ice storage device according to the present invention.

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

As shown in FIG. 1, the ice storage device 100 according to the present invention is provided with an ice container 110 in which ice can be accommodated, and is provided in the ice container 110 and accommodated in the ice container 110. It includes an ice transfer member 120 that can transfer the ice.

In addition, one side of the ice container 110 is provided with a driving device 160 for rotating the ice transfer member 120.

An ice making device 300 is provided at an upper portion of the ice storage device 100. The ice formed in the ice making device 300 is dropped and stored in the ice storage box 110 when ice making is completed.

One side of the ice container 110 is provided with a guide tube 162 for guiding the ice discharged from the ice container 110, the outlet side of the guide tube 162 selectively open and close the guide tube 162 Guide tube opening and closing member 161 is provided.

The driving device 160 may drive not only the ice transfer member 120 but also the guide tube opening and closing member 161.

A discharge tube 170 is provided below the guide tube opening and closing member 161 to guide the ice which has moved along the guide tube 162 to the dispenser (not shown).

The first ice discharge port 141 and the second ice discharge port 151 are provided at one side and the other side of the ice container 110, respectively, wherein the first ice discharge port 141 is provided at the ice transfer member 120. It is selectively opened and closed by a cylindrical rotary opening and closing member 130 is provided.

In addition, the first ice discharge port 141 is provided with an ice crushing device 142 that can be discharged by crushing the ice passing through the rotary opening and closing member 130.

Here, the ice grinding device 142 is a housing portion 143, the rotary cutter unit 144 accommodated in the housing portion 143 is provided on the axis of the rotating shaft 121 of the ice transfer member, It is accommodated in the housing portion 143, and includes a fixed cutter unit 146 for crushing the ice with the rotary cutter unit 144.

The second ice discharge port 151 is formed in the other side wall 150, and is opened and closed by the opening and closing unit 200 provided in the other side wall 150.

The ice storage device having such a configuration can be applied to a water purifier having an ice storage function as well as a refrigerator.

As shown in FIG. 2, the ice container 110 has a shape in which an upper portion thereof is opened, and the first ice discharge port 141 and the second ice discharge port 151 are provided.

As described above, the ice transfer member 120 is rotatably provided inside the ice container 110.

The ice conveying member 120 includes a rotating shaft 121 and a spiral blade-shaped conveying portion 122 provided on the outer circumferential surface of the rotating shaft 121.

The rotation opening / closing member 130 is installed at the first ice discharge port 141, and the first ice discharge port 141 periodically whenever the ice transfer member 120 rotates in the first direction (A direction). The ice is discharged.

As described above, the ice crushing device 142 is provided adjacent to the first ice discharge port 141, after the ice passes through the rotary opening and closing member 130 by the operation of the ice conveying member 120 When the ice crushing device 142 enters, the ice is crushed to form pieces of ice.

Here, the detailed configuration of the ice crushing device 142 will be described.

First, the housing portion 143 is formed in a cylindrical shape, the ice inlet 143a which is provided adjacent to the first ice discharge port 141, and the crushed ice provided in the lower portion of the housing 143 falls and discharged Ice outlet 143b is included.

In addition, the rotary cutter unit 144 provided in the housing part 143 may include a plurality of coupling shafts 144a fitted to the rotating shaft 121 and spaced apart from each other on an outer circumferential surface of the coupling shaft 144a. Rotation cutter 144b of the.

Here, one side of the rotary cutter 144b is provided with a saw blade-shaped cutting portion (144c) to facilitate the crushing of ice.

On the other hand, the fixed cutter unit 146, the ice seating portion (146a) of the opening shape that the ice passing through the rotary opening and closing member 130 is formed, and the ice seating portion (146a), the coupling shaft Fixed cutter 146b that can be fitted to 144b, and a cutting portion formed inside the fixed cutter 146b to crush and press ice together with the cutting portion 144b of the rotary cutter 144b. 146c.

The rotary cutters 144b are disposed to be spaced apart from each other, and the arrangement angles are slightly different, so that the phases of the rotating cutters 144b do not overlap with each other when viewed from the front.

This is a state where the ice is sandwiched between the cutting portion 144c of the rotary cutter 144b and the cutting portion 146c of the fixed cutter 146b, and the rotating shaft 121 rotates to apply pressure to the ice. At this time, the pressing force is to be concentrated in the rotary cutter (144b) in contact with the ice.

If the rotary cutter 144b is overlapped with each other when viewed from the front, the cutting parts 144c of the two or more rotary cutters 144b and the cutting parts 146c of the fixed cutter 146b are in the same phase. The ice is pinched in between the and the pressing force is applied to each rotating cutter, so the crushing performance of the ice decreases.

Therefore, the phases of the rotary cutter 144b are mutually different, so that when grinding is finished by one rotary cutter, grinding can be started by another rotary cutter to improve the grinding performance of the ice.

On the other hand, the fixed cutter 146b of the fixed cutter unit 146 is rotatably coupled without being fixedly coupled to the coupling shaft 144a.

Therefore, the fixed cutter 146 does not rotate even when the coupling shaft 144a and the rotary cutter 144b are rotated by the rotation of the rotary shaft 121.

The rotary cutter 144b is disposed to rotate past the fixed cutter 146b so that the rotary cutter 144b and the fixed cutter 146b do not interfere with each other.

On the other hand, the second ice discharge port 151 is provided with the opening and closing unit 200, the opening and closing member 201 provided to cover the second ice discharge port 151 of the opening and closing unit 200 is the rotating shaft ( The second ice discharge port 151 is selectively opened according to the rotation of 121.

That is, when rotating in the second direction (B direction), the second ice discharge port 151 is opened.

A rib member 112 protruding outward and surrounding the second ice discharge port 151 and the opening / closing unit 200 is provided on a sidewall of the ice container 110 in which the second ice discharge port 151 is formed. The rib member 112 is connected to the guide tube (see FIG. 1, 162) disclosed in FIG.

Thus, the ice discharged through the second ice discharge port 151 falls down along the guide tube (see FIG. 1, 162) and exits to the dispenser (not shown).

The other end of the rotary shaft 121 protrudes outwardly from the ice container 110, where the other end of the rotary shaft 121 is connected to the driving device (see Fig. 1, 160) disclosed in FIG. do.

When the driving device 160 operates, the rotating shaft 121 rotates, and accordingly, the ice transfer member 120, the opening and closing unit 200, the rotation opening and closing member 130, and the ice crushing device are rotated. 142 optionally operates.

The ice storage box 110 is provided below the storage unit 400 for storing the ice or other freezing storage or refrigerated storage as described above, the upper surface of the storage unit 400, the ice grinding device ( An inlet 430 through which ice discharged from 142 flows is provided.

Therefore, when the ice storage device of the present invention is mounted in a water purifier or a refrigerator, and the storage unit 400 serves as a water storage unit for storing water in the water purifier or the refrigerator, the ice that has entered the inlet 430 is The temperature of the water is cooled while melting in the water stored in the storage unit 400.

Then, such water can be taken out to the outside by the user's command, it is possible to quickly supply the cooling water to the user.

As shown in FIG. 3, one side of the ice container 110 is provided with a first ice discharge port 141, and a second ice discharge port 151 is provided at an inner left side of the ice container 110, and the ice transfer is performed. The member 120 may be rotated forward or reverse to move and discharge ice anywhere in the first ice discharge port 141 or the second ice discharge port 151.

On the other hand, provided in the ice container 110, the conveying unit 122 is composed of a spiral blade so as to surround the rotating shaft 121 is provided in the ice in accordance with the rotation direction of the rotating shaft 121, the first ice discharge port It may be pushed in the direction 141 or in the direction of the second ice discharge port 151.

To this end, the first ice discharge port 141 and the second ice discharge port 151 may be disposed in opposite directions to each other.

The rotary shaft 121 passes through the rotary opening and closing member 130 and the ice crushing device 142, and extends to the outermost side wall of the ice container 110, and the ice crushing device 142 is rotated. It is preferably provided between the opening and closing member 130 and the outermost side wall of the ice container 110.

On the bottom surface of the ice container 110, drain holes 180 for dissolving ice melted water are disposed to be spaced apart from each other, and the ice container 110 so that the water exiting the drain hole 180 can escape to the outside. The discharge passage 181 is provided at the bottom of the).

Here, the discharge passage 181 is disposed along the lower surface of the ice container 110, it is disposed to be inclined so that the discharge of water can be smooth.

Thus, water discharged along the discharge passage 181 is discharged to the outside by a drainage device (not shown) provided in the discharge passage 181.

A guide protrusion 190 is provided on an inner bottom surface of the ice container 110, and the guide protrusion 190 is preferably provided adjacent to the cylindrical rotary opening and closing member 130.

In the case of the rotary opening and closing member 130, due to its thickness, it takes the form of a stepped with the bottom surface of the ice container 110. When the step is formed in this way, the ice moving in the direction of the rotation opening and closing member 130 is caught by the transfer unit 122 is limited to its movement.

Therefore, a guide protrusion 190 for guiding the movement of the ice is required so that the ice can easily flow into the rotary opening and closing member 130 and then exit the first ice discharge port 141.

The guide protrusion 190 has a height corresponding to the thickness of the outer wall of the rotary opening and closing member 130, and preferably includes an inclined portion 190a so that ice can ride over.

Here, the inclined portion 190a is preferably to be inclined upward in the direction of the rotation opening and closing member 130.

As shown in FIG. 4, the rotation opening and closing member 130 is fixedly coupled to the rotation shaft 121 and is provided in a hollow cylindrical shape.

Here, the rear side of the rotary opening and closing member 130 has a form that is fully open, and the front side has a form that is partially open.

The front side of the rotary opening and closing member 130, which is partially open, is disposed to face the first ice discharge port (see FIG. 3, 141), and the first ice discharge port (FIG. 3) is prevented from discharging the ice at the front side. Reference block 141 and a blocking wall portion 131 for blocking an ice discharge path (see FIG. 3, D) formed between the ice container (see FIG. 3 and 110) and an ice discharge path (FIG. 3). And an opening 132 in communication with D).

Here, when the opening part 132 is located at the bottom and the blocking wall part 131 is located at the top, the ice is pushed by the transfer part 122 to pass through the opening part 132, and then the ice crushing device 142. After being crushed by the discharge through the first ice discharge port 141.

However, when the opening part 132 is located at the upper portion and the blocking wall portion 131 is located at the lower portion, the ice is blocked by the blocking wall portion 131 and is not discharged to the outside.

Therefore, when the rotary shaft 121 is rotated, the ice discharge path leading to the ice discharge port 141 inside the ice container 110 while the rotary opening and closing member 130 connected to the rotary shaft 121 rotates alternately. And sequentially open and shut off.

On the other hand, as shown in Figures 3 and 4 when the open portion 132 is located at the bottom, the ice discharge passage leading to the ice discharge port 141 inside the ice container 110, the ice is opened The gap L2 between the opening part 132 and the transfer part 122 positioned closest to the opening part 132 is formed to be smaller than the front and rear width L of the rotary opening and closing member so as to easily exit. It is preferable.

When the length of the L2 is formed smaller than the width or length of the ice is located in the space having the length of the L2, the ice can pass through the opening portion 132 to the ice crushing device 143.

On the other hand, the distance (L1) between the blocking wall portion 131 and the transfer portion closest to the blocking wall portion 131 is formed larger than the front and rear width (L) of the rotation opening and closing member 130, the blocking wall portion 131 Is located at the bottom and the discharge flow path between the inside of the ice container 110 and the first ice discharge port 141 is blocked, the ice that is pushed by the transfer unit 122 does not move to the blocking wall portion 131. It is desirable not to.

On the other hand, the housing 143 of the ice crushing device 142 is provided in a cylindrical shape, one side of the ice inlet 143a is provided to communicate with the opening 132 of the rotary opening and closing member 130, Ice passing through the opening 132 is introduced into the housing 143.

The ice outlet 143b through which the crushed ice is discharged is formed on the lower surface of the housing 143.

The rotary shaft 121 penetrates the rotary opening and closing member 131 and one end thereof protrudes by a predetermined length, and the rotary cutter unit 144 is mounted on the protruding portion.

Coupling shaft 144a of the rotary cutter unit 144 is provided in the hollow shape of the hollow inside is fitted to the rotary shaft 121, the plurality of rotary cutter 144b is provided on the outer peripheral surface of the coupling shaft (144a) do.

Cutting parts 144c are provided in the rotary cutters 144b, respectively, and the rotary cutters 144b are twisted with respect to each other so as to generate a phase difference therebetween to concentrate the pressing force for pressing the ice as described above. It is preferable.

In addition, the fixed cutter unit 146 is preferably provided in a shape corresponding to the shape of the opening 132, it is preferably spaced apart from each other is composed of a plurality of fixed cutter (146b).

Inside the fixed cutter 146b, the ice seating portion 146a is provided in the form of an opening to allow ice to flow therein, and the fixed cutter 146b is disposed to be spaced apart from the plurality of the openings 132. The ice passing through the ice outlet 143b passes in the direction of the plurality of fixed cutters 146b and is placed on the ice seating part 146a.

In addition, the ice seating portion 146a is disposed surrounded by the cutting portion 146c, and in this state, ice is crushed when a pressing action between the rotary cutter unit 144 and the fixed cutter unit 146 occurs. Passes down through the ice outlet 143b.

5 to 7 show various embodiments of the opening and closing unit for opening and closing the second ice discharge port 151 of the present invention.

As shown in Figure 5 (a), the ice storage container 110 is provided with a guide inclined portion 111, the ice dropped to the guide inclined portion 111 is guided by the guide inclined portion 111 It moves in the direction of the ice conveying member (see Fig. 3, 120).

On the other hand, the second ice discharge port 151 is provided in the fan shape in the ice container 110, the shape is not limited thereto.

The opening and closing unit 200 is provided to open and close the second ice discharge port 151. The opening and closing unit 200 opens and closes the second ice discharge port 151 and is rotatably coupled to the rotation shaft 121. The opening and closing member 201 is included.

In addition, two locking jaws 209a and 209b are provided on the sidewall of the ice container 110 to limit the rotation of the opening and closing member 201.

As shown in (b) of FIG. 5, the outer circumferential surface of the rotation shaft 121 is provided with a protrusion 125 that protrudes outward and rotates simultaneously with the rotation shaft 121 when the rotation shaft 121 is rotated.

The opening and closing member 201 is rotatably disposed on the rotation shaft 121, and the surface opening and closing member 201 is in contact with the protrusion 125 and the opening and closing member 201 between the opening and closing member 201 and the protrusion 125. A friction member 202 is provided to transmit the rotational force of the rotation shaft 201 to the opening and closing member 201.

In this case, when the rotation shaft 121 rotates clockwise in FIG. 5A, the protrusion 125 also rotates accordingly, and the friction member 202 in surface contact with the protrusion 125 also rotates.

Since the friction member 202 is in surface contact with the opening / closing member 201, the rotational force of the friction member 202 is also transmitted to the opening / closing member 201 so that the opening / closing member 201 is lifted up by the frictional force. do.

As a result, the second ice discharge port 151 is opened, and the ice of the ice storage box 110 is pushed to the second ice discharge port 150 by the transfer operation of the ice transfer member (see FIG. 3, 120). Discharged to the outside of the storage box 110.

At this time, the rising and closing member 201 is caught by the locking step 209a on the upper side is limited in its movement.

The rotating shaft 121 continues to rotate in the clockwise direction while the opening and closing member 201 is caught on the locking jaw 209a on the upper portion, whereby the protrusion 125 and the friction member 202 rotate. In this case, friction between the friction member 202 and the opening and closing member 201 occurs continuously.

However, since the friction force is not enough to cause deformation of the locking step 209a by the movement of the opening and closing member 201, the opening and closing member 201 is not moved anymore.

On the other hand, when the rotation of the rotating shaft 121 is stopped, it comes down by the weight of the opening and closing member 201, thereby closing the second ice discharge port 151.

When the opening and closing member 201 rotates down, the friction member 202 also rotates by the opening and closing member 202.

During this rotational movement, friction between the friction member 202 and the protrusion 125 occurs, but the frictional force is not so large as to prevent the rotational movement of the opening and closing member 201, and thus the lowering movement of the opening and closing member 201 is performed. Does not interfere with.

On the other hand, the opening and closing member 201 rotating while the lowering movement is limited to the further movement by being caught by the lower locking jaw (209b).

If the rotating shaft 121 rotates counterclockwise in a state where the opening / closing member 201 is caught on the locking jaw 209a in the upper portion, the friction force between the protrusion 125 and the friction member 201 By the frictional force between the frictional force and the opening and closing member 201, the opening and closing member 201 makes a downward rotation movement.

In addition, when the opening and closing member 201 is caught by the locking jaw 209b located below while the lower rotational movement is restricted, the lowering rotational movement is limited.

Even when the rotating shaft 121 continuously rotates in the counterclockwise direction, the opening and closing member 201 is provided on the rotating shaft so as to be rotatable, and the friction force between the friction member 202 and the opening and closing member 201 deforms the locking jaw. Since the opening and closing member 201 is not large enough, the opening and closing member 201 maintains the state in which the second ice discharge port 151 is closed while maintaining the contact state with the lower locking jaw 209b.

Here, the friction member 202 is preferably composed of a washer-type silicone ring or rubber ring.

Figure 6 shows another embodiment of the opening and closing unit.

As shown in Figure 6 (a), a guide inclination portion 111 for guiding the movement of ice is also provided on one side of the ice container 110, and the opening and closing unit 210 in the second ice discharge port 151 Is provided.

The opening and closing member 211 of the opening and closing unit 210 is also provided to rotate up and down, and the rotational movement of the opening and closing member 211 to the upper part is limited to the locking step 219a of the upper side, and to the lower side. The rotational movement is limited by the locking step 219b of the lower side.

As shown in FIG. 6 (b), a protrusion 125 is provided on an outer circumferential surface of the rotating shaft 121, and a rotating shaft gear part 213 fixed to the rotating shaft 121 is provided beside the protrusion 125. Is prepared.

The rotating shaft gear part 213 is meshed with the first transmission gear part 214 disposed next to the rotating shaft.

A second transmission gear part 216 is provided at a portion adjacent to the first transmission gear part 214, and a damper member 215 between the first transmission gear part 214 and the second transmission gear part 215. ) Is interposed.

The damper member 215 is preferably composed of a fluid damper member having a fluid therein.

The damper member 215 is characterized in that the rotational force acting on one side when rotating in one direction is transmitted to the other surface, the rotational force acting on the other surface is not transmitted to one surface when rotating in the other direction opposite to one direction. will be.

This is because the resistance of the fluid provided in the damper member 215 is formed or not formed according to the rotation direction.

The second transmission gear part 216 is engaged with the opening and closing member gear part 217 provided in the opening and closing member 211 rotatably inserted into the rotation shaft 121.

Therefore, when the rotary shaft 121 is rotated in the clockwise direction, that is, the C direction as shown in the figure, the rotary shaft gear portion 213 also rotates in the same direction.

The first transmission gear part 214 engaged with the rotary shaft gear part 213 rotates in the counterclockwise direction D.

The damper member 215 connected to the first transmission gear part 214 transfers the rotational force of the first transmission gear part 214 to the second transmission gear part 216, whereby the second transmission gear part 216 also rotates in the D direction, which is the same counterclockwise direction as the first transfer gear portion 214.

In addition, the opening and closing member gear portion 217 meshed with the second transmission gear portion 216 rotates clockwise by the motion transfer of the second transmission gear portion 216, whereby the opening and closing member ( The second ice discharge port 151 is opened while the rotary motion 211 is lifted upward.

When the opening and closing member 211 rotates, the movement of the opening and closing member 211 is limited by the locking step 219a of the upper side as in the first embodiment.

On the other hand, when the opening and closing member 211 is open to the first ice discharge port 151 in a state of being caught by the locking jaw 219a of the upper side, and at the same time the rotary shaft gear portion continuously rotates The first transmission gear part 214 rotated by 213 rotates the damper member 215.

However, the force transmitted to the second transmission gear part 216 by the damper member 215 is a force enough to lift the opening / closing member 211, but a force enough to deform the locking step 219a. Is not.

Accordingly, in the state where the opening and closing member 211 is stopped by the locking jaw 219a of the upper side, the opening and closing member gear portion 217 and the second transmission gear portion 216 engaged with the opening and closing member 211 are stopped. However, only the damper member 215 rotates in contact with the side surface of the second transmission gear part 216.

Since the rotating shaft 121 continuously rotates, ice continues to move toward the second ice discharge port 151 by a spiral blade-shaped feed unit (see FIGS. 3 and 122) installed on the rotating shaft 121, and moves outward. Discharged.

On the other hand, when the rotation of the rotating shaft 121 is stopped, the opening and closing member 211 is rotated down by its own weight, whereby the second transmission gear portion 213 is rotated in the clockwise direction. This is because the opening / closing member 211 is rotatably disposed on the rotation shaft 121.

However, since the rotational force of the second transmission gear part 216 is not transmitted to the first transmission gear part 214 by the damper member 215, the first transmission gear part 214 maintains a stopped state.

Therefore, the rotation of the second transmission gear unit 216 and the opening / closing member 217 may be smoothly performed.

In addition, the opening and closing member 211 that rotates in the descending direction is stopped by the locking jaw 219b on the lower side.

7 (a) and 7 (b) relate to a third embodiment of the opening and closing unit, wherein the opening and closing member 221 of the opening and closing unit 220 is provided to open and close the first ice discharge port 151. One side of the opening and closing member 221 is provided with an extended portion 222 extending in an arc shape and a rack gear 222a provided in the extended portion.

The rack gear 222a of the extension part 222 meshes with the driving gear part 223, and the driving gear part 223 is connected with the driving motor 224.

Therefore, when the driving motor 224 is driven, the drive gear 223 rotates, whereby the extension part 222 on which the rack gear 222a is formed is raised, and the opening and closing member 221 rotates. To open the second ice discharge port 151.

In this case, since the opening and closing member 221 is rotatably connected to the rotating shaft 121, the rotation of the opening and closing member 221 does not affect the rotating shaft 121.

That is, when the drive motor 224 rotates the drive gear 223 in the A direction, the extension portion 222 and the opening and closing member 221 also rotates in the A direction accordingly, so that the second ice discharge port 151 is opened.

When the rotary shaft 121 rotates in this state, the ice is moved to the second ice discharge port 151 by the transfer unit (see FIGS. 3 and 122) provided on the rotary shaft 121 and discharged.

In addition, when the second ice discharge port 151 is to be closed, the drive motor 224 rotates the drive gear 223 in the B direction, and thus the extension part 222 and the opening / closing member 221 are also rotated. The second ice discharge port 151 is closed by rotating in the B direction.

A locking jaw 229 is provided near the second ice discharge port 151 to limit the rotation of the opening and closing member 221. Therefore, when the opening and closing member 221 is caught by the locking jaw 229 during the closing operation, it is possible to maintain the closed state of the first ice discharge port 151 without any rotation operation of the opening and closing member 221. .

Here, the driving motor 224 may be installed on an ice making room wall that forms an ice making room in which the ice storage device (see FIG. 1 and 100) and the ice making device (see FIG. 1 and 300) are accommodated.

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

As shown in FIG. 8, when the ice transfer member 120 rotates in the A direction in a state where ice is stored in the ice container 110, a spiral blade shape provided on the rotation shaft 121 is provided. The conveying unit 122 of the ice transfers to the right.

The ice transferred by the transfer part 122 flows into the rotating switch member 130 provided in the ice transfer member 120.

The ice introduced into the rotary opening and closing member 130 passes through the opening part 132 of the rotary opening and closing member 130 and then enters into the housing part 143 of the ice crushing device 142.

And, as shown in Figure 9, the ice introduced into the housing portion 143 is placed on the ice seating portion 146a of the fixed cutter unit 146, and then rotates together with the rotary shaft 121 It is pulverized by the rotation of the rotary cutter unit 144.

In detail, a pressing action between the cutting parts 144b and 146b in a state where ice is sandwiched between the cutting part 144b of the fixed cutter unit 146 and the cutting part 144b of the rotary cutter unit 144. To be crushed.

Then, the crushed ice exits to the ice outlet 143b of the housing 143 and is discharged downward.

At this time, the opening and closing unit 200 provided in the second ice discharge port 151 blocks the second ice discharge port 151 to prevent the ice from being discharged toward the second ice discharge port 151.

At the same time, the guide tube opening and closing device 161 also maintains a state in which the guide tube 162 is closed.

As shown in FIG. 10, when the ice transfer member 120 rotates in the second rotation direction, the ice moves in the direction of the second ice discharge port 151 by the transfer unit 122.

In this case, the opening / closing unit 200 provided in the second ice discharge port 151 opens the second ice discharge port 151 according to the method disclosed in FIGS. 5 to 7. In addition, the guide tube opening and closing device 161 opens the guide tube 162 by the drive device 160.

Thus, the ice moved to the second ice discharge port 151 by the transfer unit 121 passes through the second ice discharge port 151, and then moves along the guide tube 162 and then discharges the discharge pipe ( It is discharged to the outside through the dispenser via 170).

At this time, since the ice transfer member 120 transfers the ice only in the direction of the second ice discharge port 151, the ice does not move in the direction of the second ice discharge port 141, so that the ice transfer member 120 does not move to the ice grinding member 142. Is not crushed and discharged.

100: ice storage device 110: ice storage box
120: ice feeder 121: rotating shaft
122: transfer unit 130: rotation opening and closing member
131: blocking wall 132: opening
141: first ice discharge outlet 142: ice grinding device
143: housing portion 144: rotary cutter unit
146: fixed cutter unit 151: second ice discharge outlet
200; 210; 220: switchgear 201; 211; 221: switch
202: friction member 213: rotary shaft gear
214: first transmission gear portion 215: damper member
216: second transmission gear portion 217: opening and closing member gear portion
222: extension portion 223: drive gear portion

Claims (16)

Ice storage;
A plurality of ice discharge ports provided in the ice storage box;
An ice transfer member provided in the ice storage box and selectively moving the ice to the plurality of ice discharge ports;
A rotation opening / closing member provided on one side of the ice conveying member to alternately block or open the discharge path of the ice communicating with any one of the plurality of ice outlets while rotating according to the rotation of the ice conveying member;
An opening / closing unit provided on the other side of the ice conveying member to selectively block the discharge path of the ice communicating with the other ice outlet of the plurality of ice outlets according to the rotation of the ice conveying member;
It is provided adjacent to the rotary opening and closing member includes an ice crushing device is provided to crush the ice passing through the rotary opening and closing member,
The plurality of ice discharge port, the first ice discharge port provided on one side of the ice container; And a second ice discharge port provided on the other side of the ice container, wherein the first ice discharge port and the second ice discharge port are provided on opposite sidewalls,
The ice conveying member, the rotating shaft is provided so that the forward and reverse rotation; It includes a conveying portion provided on the rotating shaft and consisting of a spiral blade formed to gradually increase in diameter toward the first ice discharge port,
The rotation opening and closing member is installed adjacent to the first ice discharge port, the opening and closing unit is ice storage device, characterized in that installed adjacent to the second ice discharge port. delete delete delete The method of claim 1,
The ice grinding device
A housing part provided adjacent to the first ice discharge port;
A rotary cutter unit accommodated in the housing part and provided at one end of the rotary shaft and configured to rotate according to the rotation of the rotary shaft;
And a fixed cutter unit fixed to the housing and configured to crush ice with the rotary cutter unit when the rotary cutter unit rotates. The method of claim 5,
One side of the rotary opening and closing member is open, the other side is composed of a hollow member that is partially open,
The rotary opening and closing member and the blocking wall portion provided on the other side;
It is provided adjacent to the blocking wall portion ice storage device, characterized in that it comprises an opening provided to pass the ice. The method of claim 6,
The ice grinding device
An ice inlet provided at one side of the housing and in communication with the opening;
Ice storage device characterized in that it comprises an ice outlet provided on the lower side of the housing of the ice crushing device is discharged crushed ice. The method of claim 7, wherein
The rotary cutter units are spaced apart from each other, but are disposed in a sequential order to include a plurality of rotary cutters having different phase angles,
The fixed cutter unit is ice storage device, characterized in that disposed between the rotary cutters so that the plurality of rotary cutters pass. 9. The method of claim 8,
The fixed cutter unit includes a plurality of fixed cutters disposed between the plurality of rotary cutters;
An ice seat portion provided in the fixed cutter and having an opening shape in which ice has passed through the opening portion;
Ice storage device, characterized in that provided in the ice seating unit and a cutter unit for crushing the ice with the cutter unit provided in the rotary cutter. 10. The method of claim 9,
The shape of the fixed cutter is an ice storage device, characterized in that formed in the shape corresponding to the shape of the opening of the rotary opening and closing member. The method of claim 6,
It is formed so as to protrude on the bottom surface of the ice container, characterized in that it further comprises a guide protrusion for guiding to move into the rotary opening and closing member while preventing the ice moving by the transfer portion to the body edge of the rotary opening and closing member. Ice storage device. delete The method of claim 1,
The opening and closing unit,
An opening and closing member rotatably provided on the rotating shaft to open and close the second ice discharge port;
A protrusion protruding from an outer circumferential surface of the rotating shaft;
And a friction member provided between the protrusion and the opening / closing member and in surface contact with the protrusion and the opening / closing member to transmit a rotational force according to the rotation of the rotary shaft to the opening / closing member. The method of claim 1,
The opening and closing unit,
An opening and closing member rotatably provided on the rotating shaft to open and close the second ice discharge port;
A rotating shaft gear part provided on an outer circumferential surface of the rotating shaft;
And a transmission gear part engaged with the rotary shaft gear part and engaged with the opening / closing member gear part provided in the opening / closing member to transfer the power of the rotary shaft gear part to the opening / closing member. Ice storage;
A plurality of ice discharge ports provided in the ice storage box;
An ice transfer member provided in the ice storage box and selectively moving the ice to the plurality of ice discharge ports;
A rotation opening / closing member provided on one side of the ice conveying member to alternately block or open the discharge path of the ice communicating with any one of the plurality of ice outlets while rotating according to the rotation of the ice conveying member;
An opening / closing unit connected to the other side of the ice conveying member and selectively blocking a discharge path of the ice communicating with one of the plurality of ice discharging outlets according to the rotation of the ice conveying member;
It is provided adjacent to the rotary opening and closing member includes an ice crushing device is provided to crush the ice passing through the rotary opening and closing member,
The plurality of ice discharge port, the first ice discharge port provided on one side of the ice container; And a second ice discharge port provided on the other side of the ice container, wherein the first ice discharge port and the second ice discharge port are provided on opposite sidewalls,
The ice conveying member, the rotating shaft is provided so that the forward and reverse rotation; It includes a conveying portion provided on the rotating shaft and consisting of a spiral blade formed to gradually increase in diameter toward the first ice discharge port,
The rotary opening and closing member is installed adjacent to the first ice discharge port, the opening and closing unit is provided with an ice storage device, characterized in that installed adjacent to the second ice discharge port. Ice storage;
A plurality of ice discharge ports provided in the ice storage box;
An ice transfer member provided in the ice storage box and selectively moving the ice to the plurality of ice discharge ports;
A rotation opening / closing member provided on one side of the ice conveying member to alternately block or open the discharge path of the ice communicating with any one of the plurality of ice outlets while rotating according to the rotation of the ice conveying member;
An opening / closing unit connected to the other side of the ice conveying member and selectively blocking a discharge path of the ice communicating with one of the plurality of ice discharging outlets according to the rotation of the ice conveying member;
It is provided adjacent to the rotary opening and closing member includes an ice crushing device is provided to crush the ice passing through the rotary opening and closing member,
The plurality of ice discharge port, the first ice discharge port provided on one side of the ice container; And a second ice discharge port provided on the other side of the ice container, wherein the first ice discharge port and the second ice discharge port are provided on opposite sidewalls,
The ice conveying member, the rotating shaft is provided so that the forward and reverse rotation; It includes a conveying portion provided on the rotating shaft and consisting of a spiral blade formed to gradually increase in diameter toward the first ice discharge port,
The rotary opening and closing member is installed adjacent to the first ice discharge port, the opening and closing unit is a water purifier having an ice storage device, characterized in that installed adjacent to the second ice discharge port.

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