KR102556424B1 - Ice quantitative supply equipment - Google Patents

Abstract

The present invention relates to an ice quantity supply device, comprising an ice storage tank having a downwardly inclined guide slope and having an ice receiving portion recessed on the front side, a rotating crane installed in the ice receiving portion, and opposite to the rotating crane. When a driving motor is installed on the outer surface of the ice storage unit to supply ice to the ice storage tank, ice is supplied to the ice storage unit along the guide slope, and a predetermined amount of ice is accommodated in the ice storage groove. A motor rotates the ice storage groove of the rotating crane to communicate with the ice discharge hole, so that a predetermined amount of ice stored in the ice storage groove is discharged through the ice discharge hole.
According to the present invention, the ice storage groove of the rotating crane is rotated to be in communication with the ice discharge hole, and a predetermined amount of ice accommodated in the ice storage groove can be discharged through the ice discharge hole. The storage groove continuously communicates with the ice discharge hole, so that the amount of ice discharged through the ice discharge hole can be easily adjusted. In addition, the discharge amount of ice stored in the ice storage tank is controlled by the rotating crane, so that ice in the ice storage tank can be controlled. There is no fear of being discharged in batches through this ice discharge hole, and the ice stored in the ice storage tank is immediately discharged through a rotating crane, reducing the ice discharge time, and the ice storage groove is designed to respond to the amount of ice requested by the user. By adjusting the number of times of communication with the discharge hole, an accurate amount of ice can be discharged.

Description

Ice quantitative supply equipment}

The present invention relates to an ice quantity supply device, and more particularly, to accommodate a predetermined amount of ice supplied into an ice receiving unit in an ice receiving groove of a rotating crane, and the rotating crane is configured such that the ice receiving groove communicates with an ice discharging hole. It relates to an ice quantity supply device that rotates and discharges a predetermined amount of ice through an ice discharge hole.

In general, a refrigerator or water purifier has a function of making ice by using cold air having a temperature much lower than the freezing point of water, and taking out the ice as ice cubes or crushing the ice into ice cubes.

An ice maker installed inside a refrigerator or water purifier to be exposed to cold air to perform this ice extraction function is a device that uses cold air in a cooling chamber to make ice, and is installed in connection with the ice maker to discharge the ice made in the ice maker to the outside. It includes an ice extraction device that guides it to be.

At this time, the ice dispensing device is a device for guiding the dispensing amount and dispensing direction of the ice produced by the ice maker.

Patent Document 1 relates to a refrigerator equipped with a conventional ice supplier. Referring to this, an ice supplier installed on an upper surface inside the freezing chamber, installed inside the freezing chamber so as to be located directly below the ice supplier, and receiving ice falling from the ice supplier An inclined passage for accommodating, a blocking/opening piece for blocking or opening the front end of the inclined passage, and an ice receiving device installed to open and close the freezing chamber and communicating with the inclined passage at one side thereof to receive ice sliding down along the inclined passage. It consists of a refrigerator door forming a pocket.

Here, a tray is formed at an upper edge of the gradient passage to induce ice falling from the ice supply device to fall in the direction of the gradient passage.

In addition, the blocking opening piece is operated to move up and down by a solenoid installed at the upper end thereof to open or block the front end of the inclined passage, so that ice in the inclined passage is supplied to the ice receiving pocket.

That is, when the operation switch unit formed on the refrigerator door is pressed and operated, the operation switch unit is maintained in a depressed state, and at this time, the ice supplier receiving the operation switch unit signal makes ice and continuously supplies the ice to the inclined passage.

In this case, the amount of ice in the inclined passage can be checked by the ice full sensor installed on the tray detecting the amount of ice accommodated in the inclined passage and outputting a signal to the outside.

Then, the operation of the operation switch is released to stop the operation of the ice supplier, and in that state, the blocking/opening piece is moved up and down by the solenoid, so that the ice accommodated in the inclined passage is supplied to the ice receiving pocket.

However, Patent Document 1 as described above takes a lot of time to obtain a predetermined amount of ice by making ice in an ice supplier and then supplying the ice to an inclined passage when operating the operation switch unit, and shortening the ice acquisition time. In the state where ice is stored in the slope passage, when the solenoid is blocked/opened, the ice in the slope passage is collectively discharged to the ice collection pocket, making it difficult to control the amount of ice discharged. When the blocking/opening piece is closed with a solenoid to block the discharge of ice, the ice is caught between the blocking/opening piece and the inclined passage, resulting in a malfunction of the machine. Also, ice in the inclined passage is discharged collectively due to the uncontrollable ice discharge. , It is impossible to obtain a relatively small amount of ice compared to the ice stored in the inclined passage, and accordingly, it is difficult to obtain an accurate amount of ice to be obtained, resulting in a decrease in reliability of the product.

KR 10-1999-0034649 A

The present invention has been made to solve the above problems, and an object of the present invention is to provide an ice storage tank having a downwardly inclined guide slope on an inner bottom surface and a recessed ice receiving portion formed on the front surface, A rotating crane that rotates in place is installed inside the unit, and a driving motor that rotates the rotating crane is installed on the outer surface of the ice container opposite to the rotating crane to supply ice to the ice storage tank, and then to the ice container along the guide slope. Ice is supplied, and a predetermined amount of ice is accommodated in the ice storage groove of the rotating crane. At this time, the drive motor rotates the ice storage groove of the rotating crane so that it communicates with the ice discharge hole, and a predetermined amount of ice accommodated in the ice storage groove An object of the present invention is to provide an ice quantity supply device that discharges ice through the ice discharge hole.

In order to achieve the object of the present invention as described above, the ice quantity supply device according to the present invention has a hollow shape, an ice inlet is formed on the upper surface, and a guide slope formed downwardly on the inner bottom surface is formed. An ice accommodating portion formed at an angle inclined in a direction opposite to the guide slope to receive ice sliding down along the guide slope and to prevent the ice from being ejected forward, and forming an ice accommodating portion on the front surface of the ice accommodating portion. an ice storage tank having an ice discharge hole formed thereon; It is installed on the inner front surface of the ice container of the ice storage tank, rotates in place around the center of the ice container, and forms an ice storage groove on its outer circumferential surface for accommodating a predetermined amount of ice that slides down into the ice container, a rotating crane rotating and moving upward so that the ice receiving groove communicates with the ice discharging hole, and discharging a predetermined amount of ice stored in the ice receiving groove into the ice discharging hole; and a drive motor installed on an outer surface of the ice container opposite to the rotating crane and connected to the rotating crane to rotate and operate the rotating crane at a predetermined angle.

In the ice quantity supply device according to the present invention, in the ice storage tank, the angle of the guide slope is formed to be inclined within 20 to 60 degrees with respect to a virtual horizontal line, and the angle of the ice container is set with a virtual vertical line as a reference. It is characterized in that it is formed inclined within 20 to 45 degrees toward the direction opposite to the guide slope.

In the ice quantity supply device according to the present invention, the ice inlet of the ice storage tank is formed directly above the guide slope to correspond to the guide slope, and guides the supply of ice to the guide slope. .

In the ice quantity supply device according to the present invention, the ice storage tank has a hollow shape, one end of which is connected to the ice discharge hole, and the other end is bent so as to face directly downward, and ice is discharged through the ice discharge hole. It is characterized in that a guide pipe for guiding to move directly downward is further formed.

In the ice quantity supply device according to the present invention, the guide pipe includes: a rotating door that is rotatably installed at one end facing the ice discharge hole and opens and closes one end of the guide pipe; an opening/closing motor installed on an outer surface of the guide pipe and having a rotating plate installed at one end thereof; and a connecting rod installed to connect between the rotating door and the rotating plate and opening and closing the rotating door while being pulled or pushed by the rotating plate.

In the ice quantity supply device according to the present invention, the rotating crane may include: a rotating body positioned in the ice container and connected to the driving motor to be rotatably operated; a space keeping ring formed at a predetermined distance from the outer circumferential surface of the rotating body and rotated integrally with the rotating body; A plurality of supporting blades formed at a predetermined interval along the outer circumferential surface of the rotating body to divide the space between the rotating body and the space keeping ring, and forming the ice receiving groove between the rotating body and the space keeping ring; to be characterized

In the ice quantity supply device according to the present invention, the rotating crane closes the ice storage grooves that cross and repeat each other among the plurality of ice storage grooves, and blocks the guide to cross discharge the ice to the ice discharge hole of the ice container. It is characterized by further forming a plate.

In the ice quantity supply device according to the present invention, the rotating crane is formed to be inclined downward within 0 to 30 degrees toward the direction of the ice discharge hole of the ice accommodating part on the outer surface of the rotating body, so that the ice accommodated in the ice accommodating groove is It is characterized in that an inclined surface for guiding the ice to slide down in the direction of the ice discharge hole is further formed.

According to the present invention, the ice storage groove of the rotating crane is rotated to be in communication with the ice discharge hole, and a predetermined amount of ice accommodated in the ice storage groove can be discharged through the ice discharge hole. The storage groove continuously communicates with the ice discharge hole, so that the amount of ice discharged through the ice discharge hole can be easily adjusted. In addition, the discharge amount of ice stored in the ice storage tank is controlled by the rotating crane, so that ice in the ice storage tank can be controlled. There is no fear of being discharged in batches through this ice discharge hole, and the ice stored in the ice storage tank is immediately discharged through a rotating crane, reducing the ice discharge time, and the ice storage groove is designed to respond to the amount of ice requested by the user. By adjusting the number of times of communication with the discharge hole, it is possible to discharge an accurate amount of ice, thereby improving the reliability of the product.

1 is a perspective view showing an ice quantity supply device according to the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is a cross-sectional perspective view showing the internal state of the ice quantity supply device according to the present invention.
Figure 4 is a side cross-sectional view of the ice quantity supply device according to the present invention.
5 is a view showing another embodiment of the rotating crane of the ice quantity supply device according to the present invention.
6 is a side cross-sectional view showing an open and closed state of a rotating door of the ice quantity supply device according to the present invention.

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

1 to 6, the ice storage tank 100 has a hollow shape, an ice inlet 101 is formed on the top surface, and a guide slope 102 is formed on the inner bottom surface to form a downward slope. The ice container 103 is recessed at a predetermined angle in an opposite direction to the guide slope 102, and accommodates ice sliding down along the guide slope 102 to prevent the ice from being discharged forward. ) is formed, and an ice discharge hole 103a is formed on the upper side of the front surface of the ice accommodating part 103.

The ice storage tank 100 receives ice through the ice inlet 101 and accommodates the ice in its internal space.

Preferably, the lower end of the ice storage tank 100 is formed in a semicircular shape so that the ice is moved to the ice container 103 in a state in which the ice is collected in the center.

The guide slope 102 guides the ice supplied into the ice storage tank 100 to slide down toward the ice container 103 .

In the ice storage tank 100, the angle θ1 of the guide slope 102 is inclined within 20 to 60 degrees with respect to the imaginary horizontal line HL.

Preferably, the angle θ1 of the guide slope 102 is perpendicular to the ice container 103 .

The ice inlet 101 of the ice storage tank 100 is formed directly above the guide slope 102 to correspond to the guide slope 102, and guides ice to be supplied to the guide slope 102.

The ice inlet 101 prevents ice from falling and being supplied to the ice container 103 .

The ice receiving part 103 receives the ice supplied into the ice storage tank 100 and allows the ice to be accommodated in the ice receiving groove 201 of the rotary crane 200 .

The diameter of the ice container 103 is proportional to the diameter of the outer circumferential surface of the rotary crane 200 and supports rotation of the rotary crane 200 .

The ice container 103 is inclined at an angle θ2 within 20 to 45 degrees toward a direction opposite to the guide slope 102 based on the imaginary vertical line VL.

The ice discharging hole 103a communicates with the ice receiving groove 201 rotated and lifted by the rotating crane 200, and allows a predetermined amount of ice accommodated in the ice receiving groove 201 to be discharged.

The ice discharge hole 103a passes the ice as it is so that the ice accommodated in the ice accommodating groove 201 is discharged by its own weight.

It is preferable that the open area of the ice dispensing hole 103a is relatively larger than the area of the ice receiving groove 201 .

The ice storage tank 100 has a hollow shape, one end of which is connected to the ice discharge hole 103a, and the other end is bent so that the ice discharge hole 103a faces directly downward. A guide pipe 104 for guiding to move to the room is further formed.

The guide pipe 104 determines the discharge direction of the ice discharged through the ice discharge hole 103a.

The guide pipe 104 is rotatably installed at one end facing the ice discharge hole 103a, and includes a rotary door 104a for opening and closing one end of the guide pipe 104, and an outer surface of the guide pipe 104. It is installed on, and the opening and closing motor 104b having a rotary plate 104b-1 installed at one end thereof and both ends are rotatably installed on each of the rotary door 104a and the rotary plate 104b-1, It further includes a connecting rod 104c that opens and closes the rotary door 104a while being pulled or pushed by the rotary plate 104b-1.

The rotating door 104a allows the ice discharged through the ice discharge hole 103a to be supplied into the guide pipe 104 while the ice is discharged through the ice discharge hole 103a.

The rotating door 104a seals the ice discharge hole 103a to prevent outside air flowing into the guide pipe 104 from flowing into the ice storage tank 100 through the ice discharge hole 103a. block it

The opening/closing motor 104b is connected to the control lever (not shown), receives a signal from the control lever (not shown), rotates the rotating plate 104b-1 in a forward or reverse direction, and rotates the connecting rod 104c. By pulling or pushing, the rotary door 104c connected to the connecting rod 104c is rotated.

The opening/closing motor 104b receives an operation stop signal of the rotary crane 200, pushes the connecting rod 104c, and seals one end of the guide pipe 104 with the rotary door 104a.

The rotating crane 200 is installed on the inner front surface of the ice container 103 of the ice storage tank 100, and rotates around the center of the ice container 103 in place as an axis so as to place the ice container 103 on its outer circumferential surface. ) to form an ice storage groove 201 for accommodating a predetermined amount of ice sliding down into the inside, and rotate the ice storage groove 201 upward so as to communicate with the ice discharge hole 103a, so that the ice storage groove 201 A predetermined amount of ice accommodated in 201 is discharged through the ice discharge hole 103a.

The rotating crane 200 is rotated at a predetermined angle by the driving motor 300 so that the ice receiving groove 201 communicates with the ice discharging hole 103a.

The rotating crane 200 allows the ice supplied into the ice accommodating part 103 to be accommodated in the ice accommodating groove 201, and the ice accommodated in the ice accommodating groove 201 is discharged through the ice discharge hole 103a. Rotate and lift in the direction.

It is preferable that the plurality of ice storage grooves 201 are formed in an annular shape and spaced apart at predetermined intervals.

The area of the ice receiving groove 201 is relatively smaller than that of the ice discharge hole 103a.

It is preferable that the rotating crane 200 is rotated by the driving motor 300 so that the plurality of ice receiving grooves 201 are aligned with the ice dispensing hole 103a.

The rotating crane 200 is located in the ice container 103 and is spaced apart from the rotating body 202 that is connected to the drive motor 300 and operated by rotation by a predetermined distance from the outer circumference of the rotating body 202. space keeping ring 203 rotated integrally with the rotating body 202, spaced apart at a predetermined interval along the outer circumferential surface of the rotating body 202 so as to partition between the rotating body 202 and the space keeping ring 203. It is composed of a plurality of supporting blades 204 forming the ice receiving groove 201 between the rotating body 202 and the space keeping ring 203 .

The rotating body 202 is rotated by the driving motor 300 to integrally rotate the space keeping ring 203 and the support blades 204 .

The rotating crane 200 is formed on the outer surface of the rotating body 202 to be inclined downward at an angle of 0 to 30 degrees toward the ice discharging hole 103a of the ice accommodating part 103, and is formed within the ice accommodating groove 201. An inclined surface 202a is further formed to guide the received ice to slide down toward the ice discharge hole 103a.

The inclined surface 202a induces the ice accommodated in the ice receiving groove 201 to slide down toward the ice discharge hole 103a by its own weight.

The gap maintaining ring 203 prevents the propeller 204 from being bent by the load of the ice supported on the propeller 204 .

The gap maintaining ring 203 is spaced apart from the inner circumferential surface of the ice accommodating part 103 so as not to interfere with the inner circumferential surface of the ice accommodating part 103 .

The support blades 204 support the ice accommodated in the ice accommodating groove 201 and guide the ice to be rotated and lifted toward the ice dispensing hole 103a.

The support blades 204 change the area of the ice accommodating groove 201 in proportion to the separation distance.

The drive motor 300 is installed on an outer surface of the ice container 103 opposite to the rotation crane 200 and is connected to the rotation crane 200 to rotate the rotation crane 200 at a predetermined angle. .

The driving motor 300 continuously rotates in the forward or reverse direction so that the ice receiving groove 201 of the rotating crane 200 passes the ice discharge hole 103a, or the ice receiving groove 201 The rotating crane 200 is continuously rotated at a predetermined angle so as to coincide with the ice discharge hole 103a.

The number of revolutions of the driving motor 300 is preferably controlled by the user.

The ice quantity supply device according to the present invention configured as described above is used as follows.

First, ice is supplied through the ice inlet 101 of the ice storage tank 100 so that the ice falls onto the guide slope 102 .

At this time, the ice supplied to the ice storage tank 100 is manually supplied by a user or supplied from an ice making device (not shown) connected to the ice inlet 101 and stored therein.

Then, the ice falling to the guide slope 102 slides along the guide slope 102 in a state of gathering in the center and is supplied into the ice container 103 .

At this time, ice enters the ice receiving groove 201 of the rotary crane 200 provided in the ice receiving portion 103, and the ice is maintained in the ice receiving groove 201.

Here, when a control lever (not shown) connected to the driving motor 300 is operated, the driving motor 300 rotates in a predetermined direction while rotating the rotating body 202 of the rotating crane 200.

At this time, the rotating plate 104b-1 of the opening/closing motor 104b installed in the guide pipe 104 receives a signal from the control lever (not shown) and rotates to pull the connecting rod 104c. Accordingly, The rotating door 104a connected to the connecting rod 104c is pulled by the connecting rod 104c to open one end of the guide pipe 104.

In addition, the control lever (not shown) is operated in a multi-stage structure to control the amount of ice discharged.

And, as the rotating body 202 rotates, the support blade 204 and the distance maintaining ring 203 are simultaneously rotated, and accordingly, the ice receiving groove 201 supported by the support blade 204 Ice is rotated and lifted by the rotating body 202 toward the ice discharging hole 103a.

At this time, the ice accommodating groove 201 accommodating ice is rotated and lifted by the rotating body 202, and at the same time, the other ice accommodating groove 201 is located at the lower end of the ice accommodating part 103, and accordingly, the guide Ice supplied into the ice container 103 along the inclined surface 102 is continuously supplied to the ice container groove 201 .

Thereafter, when the ice accommodating groove 201 accommodating ice is rotated and raised by the rotating body 202 and positioned to coincide with the ice dispensing hole 103a of the ice accommodating part 103, the ice accommodating groove ( 201) is discharged through the ice discharge hole 103a.

At this time, the ice accommodated in the ice receiving groove 201 slides down toward the ice discharge hole 103a by its own weight due to the inclined surface 202a formed on the outer surface of the rotating body 202 inclined downward.

Here, the ice accommodated in the ice receiving groove 201 is rotated and lifted in the direction of the ice discharge hole 103a in a state supported by the support blades 204, and at this time, the space keeping ring 203 moves the support By jointing the blades 204, the bearing blades 204 are prevented from being bent or deflected by the load of ice.

At this time, the ice accommodated in the ice accommodating groove 201 is rotated and lifted by its own weight in a state of being in close contact with the inner front surface of the ice accommodating part 103, and then the ice accommodating groove 201 moves up and down from the ice dispensing hole 103a. The ice is discharged in the direction of the ice discharge hole 103a by its own weight at the moment when the ice is brought into communication.

Here, the driving motor 300 receives a signal from the control lever (not shown) and continuously rotates the rotating body 202 or continuously rotates the rotating body 202 at a predetermined angle in multiple stages. .

That is, when the ice discharge amount is controlled by the control lever (not shown), the drive motor 300 rotates the rotating body 202 to correspond to the ice discharge amount, so that the ice storage of the rotating crane 200 occurs. The number of times the groove 201 communicates with the ice discharge hole 103a is determined.

Here, the ice accommodated in the ice receiving groove 201 of the rotary crane 200 is discharged through the ice discharging hole 103a, and then the ice accommodated in the other ice receiving groove 201 is discharged through the ice discharging hole ( As the ice is continuously discharged through 103a), the amount of ice discharged through the ice discharge hole 103a is determined.

In particular, when the rotating crane 200 is rotated clockwise by the drive motor 300, the left side of the ice receiving groove 201 of the rotating crane 200 is based on the ice discharge hole 103a. Ice is maintained in a state of being accommodated in each of the ice discharging holes 103a located at , and the ice receiving groove 201 through which ice is discharged through the ice discharging hole 103a is located on the right side thereof.

The ice discharged through the ice discharge hole 103a enters the guide pipe 104 through the open end of the guide pipe 104, and is then guided through the guide pipe 104 to a downward direction. is discharged towards

At this time, as described above, the ice discharge hole 103a is discharged through one end of the guide pipe 104 opened by the opening/closing motor 104b and the connecting rod 104c.

Thereafter, when the ice discharge is completed through the ice discharge hole 103a, the rotating plate 104b-1 of the opening/closing motor 104b is rotated to push the connecting rod 104c, and at this time, the connecting rod 104c ) is returned to its original position and one end of the guide pipe 104 is sealed, so that the flow of outside air flowing into the ice storage tank 100 through the guide pipe 104 moves through the rotary door Blocked by 104a, the ice cooling state in the ice storage tank 100 is maintained.

At this time, the opening/closing motor 104b receives a signal from the rotating crane 200 and is rotated to push the connecting rod 104c at the moment when the operation of the rotating crane 200 is stopped, and the guide pipe 104 ) is to block one.

Meanwhile, when the rotating crane 200 is continuously rotated by the driving motor 300 so that the ice receiving groove 201 passes the ice discharging hole 103a, the ice receiving groove 201 Blocking plates 205 are formed in the ice receiving grooves 201 that are alternately crossed with each other, so that the ice receiving grooves 201 pass the ice dispensing hole 103a and discharge ice into the ice dispensing hole 103a. will emit

That is, by repeatedly accommodating ice in the ice receiving groove 201, the ice receiving groove 201 communicates with the ice discharging hole 103a to discharge ice into the ice discharging hole 103a. The blocking plate 205 communicates with the ice discharging hole 103a, and ice is discharged into the ice discharging hole 103a with a time difference.

Here, when the rotation of the rotating crane 200 is stopped by the drive motor 300, the blocking plate 205 of the rotating crane 200 is positioned so as to coincide with the ice discharge hole 103a, and the ice Ice is prevented from being discharged into the discharge hole 103a.

As described above, the ice supplied to the ice receiving unit 103 is accommodated in the ice receiving groove 201 of the rotating crane 200, and the ice receiving groove 201 rotates and moves up and down so that the ice receiving groove 201 communicates with the ice discharge hole 103a. The structure in which a predetermined amount of ice accommodated in the ice receiving groove 201 is discharged through the ice discharging hole 103a is such that the ice receiving groove 201 of the rotating crane 200 communicates with the ice discharging hole 103a. By rotating, a predetermined amount of ice accommodated in the ice receiving groove 201 can be discharged through the ice discharging hole 103a, and the plurality of ice receiving grooves 201 are discharged through the ice discharging hole 103a while rotating the rotating crane 200. 103a, the amount of ice discharged through the ice discharge hole 103a can be easily adjusted, and the amount of ice stored in the ice storage tank 100 is controlled by the rotating crane 200. , there is no fear that the ice in the ice storage tank 100 will be collectively discharged through the ice discharge hole 103a.

The ice quantity supply device according to the present invention described above is not limited to the above embodiments, and anyone having ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the following claims There is a technical spirit to the extent that it can be implemented by changing variously.

100: ice storage tank 101: ice inlet
102: guide slope 103: ice receiving unit
103a: ice discharge hole 104: guide pipe
104a: rotating door 104b-1: rotating plate
104b: open/close motor 104c: connecting rod
200: rotating crane 201: ice storage groove
202: rotating body 202a: inclined surface
203: spacing ring 204: support wing
205: blocking plate 300: drive motor
HL: horizontal line VL: vertical line

Claims (8)

In a hollow shape, an ice inlet 101 is formed on the upper surface, and a guide slope 102 formed downwardly on the inner bottom surface is formed, and the front surface is recessed at an angle determined in the opposite direction to the guide slope 102. An ice accommodating part 103 is formed to accommodate the ice sliding down along the guide slope 102 and prevent the ice from escaping and discharged forward, and the ice accommodating part 103 is placed on the upper side of the front surface. an ice storage tank 100 having a discharge hole 103a;
It is installed on the inner front surface of the ice container 103 of the ice storage tank 100, rotates around the center of the ice container 103 in place, and slides down into the ice container 103 on its outer circumferential surface. An ice receiving groove 201 accommodating an amount of ice is formed, and the ice receiving groove 201 is rotated and moved upward to communicate with the ice discharging hole 103a, so that a predetermined amount of ice accommodated in the ice receiving groove 201 is formed. a rotating crane 200 discharging an amount of ice into the ice discharging hole 103a;
A drive motor 300 installed on an outer surface of the ice container 103 opposite to the rotation crane 200 and connected to the rotation crane 200 to rotate the rotation crane 200 at a predetermined angle;
consists of,
The ice storage tank 100,
It has a hollow shape, one end of which is connected to the ice discharge hole 103a and the other end is bent so that the ice discharge hole 103a of the ice container 103 faces directly downward. Further forming a guide pipe 104 for guiding to move to,
The guide pipe 104,
a rotating door (104a) rotatably installed at one end facing the ice discharge hole (103a) to open and close one end of the guide pipe (104);
An opening/closing motor (104b) installed on an outer surface of the guide pipe (104) and having a rotating plate (104b-1) installed at one end thereof; and
Both ends are rotatably installed on each of the rotary door 104a and the rotary plate 104b-1, and are pulled or pushed by the rotary plate 104b-1 to open and close the rotary door 104a. 104c);
Including more,
The rotating crane 200,
a rotating body 202 located in the ice container 103 and connected to the driving motor 300 to operate rotationally;
A space keeping ring 203 formed to be spaced apart from the outer circumferential surface of the rotating body 202 by a predetermined distance and rotated integrally with the rotating body 202;
The rotating body 202 and the spacing keeping ring 203 are formed in a plurality of pieces spaced apart at a predetermined interval along the outer circumferential surface of the rotating body 202 to partition between the rotating body 202 and the space keeping ring 203. Support blades 204 forming the ice receiving groove 201 therebetween;
consists of,
The rotating crane 200,
A blocking plate for guiding ice to be cross-discharged to the ice discharging hole 103a of the ice receiving part 103 by closing the ice receiving grooves 201 that cross and repeat among the plurality of ice receiving grooves 201 ( 205) further form,
The rotating crane 200,
The outer surface of the rotating body 202 is inclined downward at an angle of 0 to 30 degrees toward the ice discharging hole 103a of the ice accommodating part 103, so that the ice accommodated in the ice accommodating groove 201 is passed through the ice discharging hole. An ice quantity supply device characterized in that an inclined surface 202a is further formed to guide the sliding down in the direction of (103a). According to claim 1,
The ice storage tank 100,
The angle θ1 of the guide slope 102 is inclined within 20 to 60 degrees with respect to the virtual horizontal line HL,
Ice quantity supply device, characterized in that the angle (θ2) of the ice receiving portion (103) is inclined within 20 to 45 degrees toward the direction opposite to the guide slope (102) based on a virtual vertical line (VL). . According to claim 1,
The ice inlet 101 of the ice storage tank 100,
The ice quantity supply device, characterized in that it is formed directly above the guide slope (102) to correspond to the guide slope (102), and guides the ice to be supplied to the guide slope (102). delete delete delete delete delete

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