CN210242118U - Ice conveying assembly and ice dispenser - Google Patents

Abstract

The utility model provides an ice-cube conveying subassembly and ice-cube distributor relates to ice-making equipment's technical field, ice-cube conveying subassembly includes the carousel, be provided with the convex structure of dialling ice on the terminal surface of carousel, dial the ice structure can the carousel rotate the time will with dial the ice-cube of ice structure contact and dial. During the use, ice-cube conveying assembly installs inside the ice storage bucket, the ice-cube is placed to ice storage bucket inside, edges and corners on the ice-cube with the terminal surface contact who states the carousel, when the carousel rotated, it can with to dial the ice structure the edges and corners of ice-cube are dialled and are opened, prevent that the edges and corners from continuously rubbing the terminal surface of carousel, thereby improve the stability of carousel avoids the carousel breaks.

Description

Ice conveying assembly and ice dispenser

Technical Field

The utility model belongs to the technical field of ice-making equipment's technique and specifically relates to an ice-cube conveying assembly and ice-cube distributor are related to.

Background

With the advent of the hot summer season, customers and consumers prefer to place ice in their beverages, and therefore many fast food restaurants are provided with ice dispensers to place ice in the beverages of the customers and consumers.

The existing ice distributor of the ice maker comprises an ice storage barrel, wherein an ice outlet is formed in the ice storage barrel, a turntable is arranged in the ice storage barrel, and a shifting piece is arranged on the circumferential side wall of the turntable and can be used for shifting ice blocks in the ice storage barrel to the ice outlet along with the rotation of the turntable.

A lot of ice-cubes have been stored in the ice-storage barrel, and some ice-cubes have sharp edges and corners, and when the carousel rotated, this inner end face of friction that the edges and corners on the ice-cube of the inner end face contact with the carousel can last to the terminal surface in the fish tail, long-term in the past, the structural stability of carousel reduced, lead to the carousel to break.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an ice-cube conveying subassembly and ice-cube distributor to in solving current ice-cube distributor, when the carousel rotates, with this interior terminal surface of friction that the edges and corners on the ice-cube of the interior terminal surface contact of carousel can last, thereby terminal surface in the fish tail, permanent in the past, the structural stability of carousel reduces, leads to the cracked technical problem of carousel.

In a first aspect, the utility model provides an ice-cube conveying subassembly, ice-cube conveying subassembly includes the carousel, be provided with the convex structure of dialling ice on the terminal surface of carousel, dial the ice structure can the carousel rotate the time will with dial the ice-cube of ice structure contact and dial away the terminal surface.

Further, the ice-poking structure comprises an ice-poking blocking strip, and the ice-poking blocking strip extends along the radial direction of the turntable;

the number of the ice poking barrier strips is multiple.

Further, a shaft sleeve structure is arranged at the center of the rotary table, a shaft hole is formed in the center of the shaft sleeve structure, and the center of the shaft hole is aligned with the center of the rotary table;

and a reinforcing rib is arranged between the outer side wall of the shaft sleeve structure and the end surface of the turntable.

Furthermore, the strengthening rib is followed the radial outside towards of carousel extends, dial the ice blend stop certainly the border of carousel extends to the center of carousel, and follows in the radial direction of carousel, the length of strengthening rib with dial the length sum of ice blend stop more than or equal to the radius of carousel.

Further, the ice conveying assembly comprises a stirring rod, and one end of the stirring rod is connected with the rotary disc;

the stirring rod is provided with a stirring fin which is used for stirring ice blocks.

Further, the stirring wings are U-shaped structural members, and openings of the U-shaped structural members face the stirring rods.

In a second aspect, the present invention provides an ice dispenser comprising an ice delivery assembly.

Further, the ice dispenser comprises an ice storage barrel and a water receiving barrel, the water receiving barrel is arranged below the ice storage barrel, and the ice conveying assembly is arranged in the ice storage barrel;

the ice storage barrel is provided with an ice outlet and a water drain hole, and ice blocks pushed out by the ice block conveying assembly can be discharged from the ice outlet;

the drain hole is used for draining water for melting the ice blocks in the ice storage barrel into the water receiving barrel.

Further, a first protruding structure protruding outwards is arranged on the outer wall of the front side face of the ice storage barrel, and a first concave structure recessed towards the inner side of the ice storage barrel is arranged on the first protruding structure;

a second concave structure which is concave outwards is arranged on the inner wall of the front side surface of the ice storage barrel, a second convex structure which is convex towards the inner side of the ice storage barrel is arranged on the second concave structure, the first convex structure corresponds to the second concave structure, and the first concave structure corresponds to the second convex structure;

the upper part of the first convex structure is in arc transition with the outer wall of the front side surface of the ice storage barrel, and the lower part of the first convex structure is in arc transition with the first concave structure; the upper part of the second concave structure is in arc transition with the inner wall of the front side surface of the ice storage barrel, and the lower part of the second concave structure is in arc transition with the second convex structure;

a gap is reserved between the inner wall of the first protruding structure and the outer wall of the second protruding structure to form a turntable groove for containing the turntable.

Further, the ice dispenser comprises a shell, wherein a mounting groove is formed in the shell, and a panel is detachably mounted in the mounting groove;

the panel is provided with a first opening communicated with the ice outlet of the ice storage barrel and a second opening communicated with the water receiving barrel;

the first opening is communicated with the ice outlet through an ice outlet pipeline.

The utility model provides an ice-cube conveying subassembly, ice-cube conveying subassembly includes the carousel, be provided with the convex structure of dialling ice on the terminal surface of carousel, dial the ice structure can the carousel rotate the time will with dial the ice-cube of ice structure contact and dial, during the use, the edges and corners on the ice-cube with the end face contact of carousel, when the carousel rotates, dial the ice structure can with the edges and corners of ice-cube are dialled, prevent that the edges and corners from continuously rubbing the terminal surface of carousel, thereby improve the stability of carousel is avoided the carousel breaks.

The utility model provides an ice cube distributor, including foretell ice cube conveying assembly, so, the embodiment of the utility model provides an ice cube distributor also possesses ice cube conveying assembly's advantage.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic view of an ice conveying assembly provided in embodiment 1 of the present invention;

fig. 2 is a schematic view of a turntable of an ice conveying assembly provided in embodiment 1 of the present invention;

fig. 3 is a front view of a turntable of an ice conveying assembly provided in embodiment 1 of the present invention;

fig. 4 is a front view of a turntable of an ice conveying assembly provided in embodiment 2 of the present invention;

fig. 5 is a front view of a turntable of an ice conveying assembly provided in embodiment 3 of the present invention;

fig. 6 is a front view of a turntable of an ice conveying assembly provided in embodiment 4 of the present invention;

fig. 7 is a cross-sectional view of an ice cube transfer dispenser according to an embodiment of the present invention;

fig. 8 is a schematic view of an internal structure of an ice storage bin of an ice dispenser according to an embodiment of the present invention;

fig. 9 is a schematic view of a face plate of an ice cube dispenser according to an embodiment of the present invention;

fig. 10 is a schematic view of an external structure of an ice storage bin of an ice cube dispenser according to an embodiment of the present invention.

Icon: 100-an ice delivery assembly; 110-a turntable; 111-ice-pulling barrier strip; 112-a plectrum; 113-a sleeve structure; 114-shaft hole; 115-reinforcing ribs; 121-a stirring rod; 122-stirring fins; 200-an ice storage barrel; 201-a first projection arrangement; 202-a second projection structure; 203-a first recessed structure; 204-a second recessed structure; 210-a turntable slot; 220-ice outlet; 230-a first via; 240-second via; 250-drain hole; 310-a housing; 320-a panel; 321-a first opening; 322-a second opening; 323-shelf; 400-water receiving barrel; 510-an electric motor; 520-a reducer; 610-an ice outlet pipeline; 620-ice receiving nozzle.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1

As shown in fig. 1-3, the utility model provides an ice cube conveying assembly 100, ice cube conveying assembly 100 includes carousel 110, be provided with the protruding structure of dialling ice on the terminal surface of carousel 110, it can be in to dial the ice cube that the structure contacted will with when carousel 110 rotates dials the ice cube that the structure contacted.

During the use, ice-cube conveying assembly 100 installs inside ice storage bucket 200, ice-cube is placed to ice storage bucket 200 inside, the edges and corners on the ice-cube with state the terminal surface contact of carousel 110, when carousel 110 rotated, it can be with to dial the ice-cube edges and corners open, prevents that the edges and corners from continuously rubbing the terminal surface of carousel 110, thereby improves carousel 110's stability avoids carousel 110 breaks.

Specifically, the circumferential side wall of the turntable 110 is provided with a pick 112, and as the turntable 110 rotates, the pick 112 can convey ice to the ice outlet 220, and a user can use the container to take ice.

The turntable 110 is made of PP (Polypropylene, abbreviated as PP) plastic by injection molding.

As shown in fig. 2, the ice-shifting structure includes an ice-shifting bar 111, and the ice-shifting bar 111 extends in a radial direction of the turntable 110. The ice-removing barrier 111 is a linear barrier arranged along the radial direction of the turntable 110, and the extending direction thereof is the length direction, and the length dimension is greater than the width dimension thereof.

The projection shape of the ice-ejecting bar 111 on the end surface of the turntable 110 may not be a straight line, but may be a curved line, and the projection shape is distributed on the end surface of the turntable 110, and can also play a role in ejecting ice cubes.

Preferably, the number of the ice-picking bars 111 is multiple, and the ice-picking bars are uniformly arranged on the end surface of the turntable 110 and extend along the radial direction of the turntable 110. The edges and corners of the ice blocks abutted to the turntable 110 can be poked away more timely by the ice poking bars 111, the surface of the turntable 110 is more effectively prevented from being scratched by the ice blocks, and the turntable 110 can be uniformly stressed when the turntable 110 rotates.

As shown in fig. 3, a shaft sleeve structure 113 is disposed at the center of the turntable 110, a shaft hole 114 is disposed at the center of the shaft sleeve structure 113, and the center of the shaft hole 114 is aligned with the center of the turntable 110;

specifically, a shaft sleeve structure 113 aligned with the center of the rotary table 110 is disposed on the end surface of the rotary table 110, the shaft hole 114 is disposed at the center of the shaft sleeve structure 113, and the shaft hole 114 is used for connecting the stirring rod 121. When the turntable 110 rotates, the shaft sleeve structure 113 can make the rotation of the turntable 110 more stable, and plays a role in supporting the turntable 110.

It should be noted that the shaft sleeve structure 113 may be made of a metal material, and is directly embedded on the turntable 110 when the turntable 110 is injection molded, so as to fixedly connect the shaft sleeve structure 113 and the turntable 110.

A reinforcing rib 115 is arranged between the outer side wall of the shaft sleeve structure 113 and the end face of the rotary table 110, and the reinforcing rib 115 is connected with the shaft sleeve structure 113 and the rotary table 110, so that the rotary table 110 is uniformly stressed, the stability of the rotary table 110 during rotation is further improved, and the strength of the shaft sleeve structure 113 is also improved.

The ice conveying assembly 100 includes a stirring rod 121, and one end of the stirring rod 121 is connected to the turntable 110.

Specifically, one end of the stirring rod 121 is connected to the shaft hole 114.

In this embodiment, the shaft hole 114 is a hexagonal hole, and one end of the stirring rod 121 is a hexagonal shaft corresponding to the shaft hole 114, and the two are matched together, so that the stirring rod 121 and the rotating disc 110 can rotate synchronously.

The shaft hole 114 may have another polygonal shape, and one end of the stirring rod 121 may have a structure corresponding to the polygonal shape, so that the stirring rod 121 and the turntable 110 can rotate in synchronization.

The stirring rod 121 is made of stainless steel.

The stirring rod 121 is provided with a stirring fin 122, the stirring fin 122 is used for stirring ice cubes, and when the turntable 110 rotates, the stirring rod 121 and the stirring fin 122 rotate to stir the ice cubes in the ice storage barrel 200, so as to assist the turntable 110 to smoothly discharge the ice cubes.

Preferably, the stirring fin 122 is a U-shaped structure, and an opening of the U-shaped structure faces the stirring rod 121.

Particularly, the existing ice dispenser of the ice maker has the fork-shaped stirring part, the size is large, the turning radius is large, the machine is greatly vibrated during stirring, the operation is not stable, and even when the ice storage barrel 200 is full of ice, the ice is even broken to the bottom of the ice maker during stirring, so that certain potential safety hazards are caused. In this embodiment, the shape of the stirring rod 121 is improved, the stirring rod 121 is changed into a double-U-shaped symmetrical distribution, and the turning radius of the stirring rod is reduced, so that the stirring rod 121 is uniformly stressed, the operation vibration is small, and the operation safety is ensured.

Example 2

As shown in fig. 4, the difference from embodiment 1 is that the ice-poking bar 111 extends from the center of the turntable 110 to the edge of the turntable 110.

Specifically, the ice-removing barrier 111 may be a linear type extending from the center of the turntable 110 to the edge of the turntable 110, and when the turntable 110 rotates, the ice-removing barrier 111 rotates along with the turntable 110, so that the area covered by the rotated ice-removing barrier 111 is the same as the area of the end surface of the turntable 110, and ice cubes at any position on the end surface of the turntable 110 can be removed.

The projection shape of the ice-shifting bar 111 on the end surface of the turntable 110 may also be a curve, such as an arc shape, an S shape, etc., so as to satisfy the requirement that the center of the turntable 110 is communicated with the edge of the turntable 110.

Example 3

As shown in fig. 5, the difference from embodiment 1 is that the reinforcing ribs 115 extend to the edge of the turntable 110.

Specifically, the reinforcing rib 115 extends from the shaft sleeve structure 113 to the outer side in the radial direction of the turntable 110, and to the edge of the turntable 110, the reinforcing rib 115 not only can be used for improving the stability of the turntable 110 during rotation and the strength of the shaft sleeve structure 113, but also can play the same role as the ice-removing barrier 111, that is, the ice-removing barrier 111 and the reinforcing rib 115 together form the ice-removing structure.

Preferably, along the edge direction of the shaft sleeve structure 113 toward the rotating disc 110, the distance between the surface of the reinforcing rib 115 facing away from the rotating disc 110 and the rotating disc 110 is gradually reduced, so that the advantage is that, at the position close to the shaft sleeve structure 113, the distance between the surface of the reinforcing rib 115 facing away from the rotating disc 110 and the rotating disc 110 is relatively larger, so as to improve the strength of the shaft sleeve structure 113; at a position far away from the sleeve structure 113, a distance between a surface of the reinforcing rib 115 facing away from the turntable 110 and the turntable 110 is relatively small, and the reinforcing rib can function as the ice-picking bar 111.

Example 4

As shown in fig. 6, the difference from embodiment 1 is that the reinforcing rib 115 extends outward in the radial direction of the turntable 110, the ice-removing bar 111 extends from the edge of the turntable 110 to the center of the turntable 110, and the sum of the length of the reinforcing rib 115 and the length of the ice-removing bar 111 is greater than or equal to the radius of the turntable 110 in the radial direction of the turntable 110.

Specifically, the extending direction of the reinforcing rib 115 is different from the extending direction of the ice-picking bar 111, that is, the reinforcing rib 115 and the ice-picking bar 111 are arranged in a staggered manner, and at this time, the sum of the length of the reinforcing rib 115 and the length of the ice-picking bar 111 is greater than or equal to the radius of the turntable 110. When the turntable 110 rotates, the reinforcing rib 115 and the ice-picking bar 111 together can ensure that all ice cubes contacting with the turntable 110 can be picked by the reinforcing rib 115 and the ice-picking bar 111.

In addition, the extending direction of the reinforcing rib 115 is the same as the extending direction of the ice-picking bar 111, and in this case, the sum of the length of the reinforcing rib 115 and the length of the ice-picking bar 111 is equal to the radius of the turntable 110. When the turntable 110 rotates, the reinforcing ribs 115 and the ice-picking bars 111 work together, and it can also be ensured that all ice blocks contacting with the turntable 110 can be picked by the reinforcing ribs 115 and the ice-picking bars 111.

To sum up, the utility model provides an ice-cube conveying subassembly 100, ice-cube conveying subassembly 100 includes carousel 110, be provided with the convex structure of dialling ice on the terminal surface of carousel 110, dial the ice structure can carousel 110 rotate the time will with dial the ice-cube of ice structure contact and dial out, during the use, the edges and corners on the ice-cube with state carousel 110's end face contact, when carousel 110 rotates, dial the ice structure can with the edges and corners of ice-cube are dialled out, prevent that the edges and corners from continuously rubbing carousel 110's terminal surface, thereby improve carousel 110's stability is avoided carousel 110 breaks.

As shown in fig. 7 to 9, an ice dispenser includes the ice transfer assembly 100, the ice storage bin 200, the water receiving bin 400, the driving mechanism, and the housing 310. The ice conveying assembly 100 is arranged in the ice storage barrel 200, the water receiving barrel 400 is arranged below the ice storage barrel 200, the driving mechanism is arranged outside the ice storage barrel 200, the output end of the driving mechanism penetrates through the outer wall of the ice storage barrel 200 and then is connected with the turntable 110 and used for driving the turntable 110 to rotate, and the ice conveying assembly 100, the ice storage barrel 200, the water receiving barrel 400 and the driving mechanism are all arranged inside the shell 310.

Specifically, the ice dispenser includes an ice storage bin 200 and a water receiving bin 400, the water receiving bin 400 is disposed below the ice storage bin 200, the ice conveying assembly 100 is obliquely disposed in the ice storage bin 200, and a water level position of an end of the stirring rod 121 far away from the turntable 110 is higher than a water level position of an end of the stirring rod near the turntable 110.

The bottom of the ice storage barrel 200 is provided with a drainage hole 250, the water receiving barrel 400 is positioned below the drainage hole 250, and the drainage hole 250 is used for draining water for melting ice cubes in the ice storage barrel 200 into the water receiving barrel 400.

As shown in fig. 8 and 10, a first protruding structure 201 protruding outward is disposed on an outer wall of a front side of the ice bank 200, and a first recessed structure 203 recessed toward an inner side of the ice bank 200 is disposed on the first protruding structure 201; a second concave structure 204 which is concave outwards is arranged on the inner wall of the front side surface of the ice storage barrel 200, a second convex structure 202 which is convex towards the inner side of the ice storage barrel 200 is arranged on the second concave structure 204, the first convex structure 201 corresponds to the second concave structure 204, and the first concave structure 203 corresponds to the second convex structure 202.

The upper part of the first convex structure 201 is in arc transition with the outer wall of the front side of the ice storage barrel 200, and the lower part of the first convex structure 201 is in arc transition with the first concave structure 203; the upper portion of the second recess structure 204 is in arc transition with the inner wall of the front side of the ice bank 200, and the lower portion of the second recess structure 204 is in arc transition with the second protrusion structure 202. Due to the adoption of the arc smooth transition, the ice storage barrel 200 can be processed by a plastic uptake process, so that the processing size error is reduced, the precision is improved, and the cost is finally saved.

A gap is formed between the inner wall of the first protruding structure 201 and the outer wall of the second protruding structure 202 to form a turntable slot 210 for accommodating the turntable 110.

A first through hole 230 is arranged in the center of the second protruding structure 202, and the first through hole 230 is used for connecting the output end of the driving mechanism with the turntable 110 after passing through; a second through hole 240 is formed on a rear side of the ice bank 200 opposite to the first through hole 230, and the second through hole 240 is used to be connected to the other end of the stirring rod 121 and can support the stirring rod 121.

The horizontal position of the first through hole 230 is lower than that of the second through hole 240, and the center line of the first through hole 230 coincides with the center line of the second through hole 240. And the center lines of the first through hole 230 and the second through hole 240 are perpendicular to the on-plane of the turntable slot.

As shown in fig. 7, in the present embodiment, the driving mechanism includes an electric motor 510 and a speed reducer 520, an output end of the electric motor 510 is connected to an input end of the speed reducer 520, and an output end of the speed reducer 520 is connected to the shaft hole 114 of the end surface of the turntable 110 facing away from the stirring rod 121. The electric motor 510 and the reducer 520 are conventional and will not be described herein.

It should be noted that the driving mechanism may also be a manual rotating wheel, the manual rotating wheel is connected to the rotating disc 110, and when ice cubes are needed, a user may rotate the manual rotating wheel by hand, so as to drive the rotating disc 110 to rotate.

The ice storage barrel 200 may be formed by processing an inner container and stainless steel plating coated outside through a foaming process. The inner container has the heat preservation function and is processed by adopting the plastic suction process, the inner container can only be processed by rotational moulding in the prior art, the processing size error is large, the precision is low, and the cutting processing efficiency is low. Through improving the design, make it can come out with the blister processing, put forward and improved machining precision and efficiency greatly.

The ice storage bin 200 is provided with an ice outlet 220, and the ice cubes pushed out by the ice cube conveying assembly 100 can be discharged from the ice outlet 220.

Specifically, the ice outlet 220 is disposed at an upper portion of the tray groove 210 and on a moving path of the paddle 112 of the turntable 110, and ice cubes are transferred to the ice outlet 220 by the paddle 112 when the turntable 110 rotates.

As shown in fig. 7 and 9, the ice dispenser includes a housing 310, wherein a mounting groove is formed on the housing 310, the mounting groove is a region for receiving ice cubes, the housing 310 includes a panel 320 detachable from the mounting groove, and the panel 320 is provided with a first opening 321 communicated with the ice outlet 220 of the ice storage bin 200 and a second opening 322 communicated with the water receiving bin 400;

specifically, the panel 320 is a concave structure, the first opening 321 is disposed at the upper end of the panel 320, the first opening 321 is communicated with the ice outlet 220 through an ice outlet duct 610, an ice receiving nozzle 620 is disposed at the first opening 321, when in use, the turntable 110 is rotated, ice cubes are conveyed to the ice outlet 220 by using the pick-up, the ice cubes reach the ice receiving nozzle 620 at the upper end of the panel 320 through the ice outlet duct 610, and a user can receive the ice cubes with a cup.

The second opening 322 is disposed at the lower end of the panel 320, and the water receiving bucket 400 is disposed at the lower end of the second opening 322. In actual use, the excess water or ice blocks can be directly discharged into the water receiving barrel 400 below the water receiving barrel.

The second opening 322 may also be communicated with the water receiving barrel 400 through a pipe.

Preferably, a shelf 323 is disposed on the second opening 322, the shelf 323 can be used for placing a cup or other container for receiving the ice cubes of the ice receiving nozzle 620, the shelf 323 is a net structure, and the excess water and smaller ice cubes can fall into the water receiving barrel 400 through the second opening 322.

The panel 320 may be formed by a blister process.

The ice outlet area of the existing ice dispenser of the ice maker is processed by integral injection molding and is formed into a whole with the panel 320 by injection molding, so that the existing ice dispenser of the ice maker is high in processing cost and is more inconvenient to assemble and disassemble for after-sale maintenance. In this embodiment, the panel 320 is designed to be a single blister, and can be separately installed and detached, so that the processing cost is reduced, the assembly efficiency is improved, and the maintenance is more convenient.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. The ice block conveying assembly is characterized by comprising a rotary disc, wherein a protruding ice poking structure is arranged on the end face of the rotary disc, and the ice poking structure can poke ice blocks which are in contact with the ice poking structure away from the end face when the rotary disc rotates.

2. The ice cube conveying assembly of claim 1, wherein the ice plucking structure comprises an ice plucking bar extending in a radial direction of the carousel;

the number of the ice poking barrier strips is multiple.

3. The ice cube conveying assembly of claim 2, wherein a hub structure is disposed in a center of the turntable, the hub structure having an axial hole disposed in a center thereof, the axial hole having a center aligned with a center of the turntable;

and a reinforcing rib is arranged between the outer side wall of the shaft sleeve structure and the end surface of the turntable.

4. The ice cube conveying assembly according to claim 3, wherein the reinforcing ribs extend radially outward of the turntable, the ice-ejecting barrier extends from an edge of the turntable toward a center of the turntable, and a sum of a length of the reinforcing ribs and a length of the ice-ejecting barrier is greater than or equal to a radius of the turntable in a radial direction of the turntable.

5. The ice cube conveying assembly of claim 1, comprising a stirring rod, one end of the stirring rod being connected to the turntable;

the stirring rod is provided with a stirring fin which is used for stirring ice blocks.

6. The ice cube conveying assembly of claim 5, wherein the stirring fin is a U-shaped structure having an opening facing the stirring rod.

7. An ice dispenser comprising an ice delivery assembly as claimed in any one of claims 1 to 6.

8. The ice dispenser of claim 7, wherein the ice dispenser comprises an ice storage bin and a water receiving bin, the water receiving bin disposed below the ice storage bin, the ice transfer assembly disposed within the ice storage bin;

the ice storage barrel is provided with an ice outlet and a water drain hole, and ice blocks pushed out by the ice block conveying assembly can be discharged from the ice outlet;

the drain hole is used for draining water for melting the ice blocks in the ice storage barrel into the water receiving barrel.

9. The ice dispenser of claim 8, wherein a first protrusion protruding outward is formed on an outer wall of the front side of the ice bank, and a first recess depressed toward the inside of the ice bank is formed on the first protrusion;

a second concave structure which is concave outwards is arranged on the inner wall of the front side surface of the ice storage barrel, a second convex structure which is convex towards the inner side of the ice storage barrel is arranged on the second concave structure, the first convex structure corresponds to the second concave structure, and the first concave structure corresponds to the second convex structure;

the upper part of the first convex structure is in arc transition with the outer wall of the front side surface of the ice storage barrel, and the lower part of the first convex structure is in arc transition with the first concave structure; the upper part of the second concave structure is in arc transition with the inner wall of the front side surface of the ice storage barrel, and the lower part of the second concave structure is in arc transition with the second convex structure;

a gap is reserved between the inner wall of the first protruding structure and the outer wall of the second protruding structure to form a turntable groove for containing the turntable.

10. The ice dispenser of claim 9, including a housing having a mounting slot with a panel removably mounted therein;

the panel is provided with a first opening communicated with the ice outlet of the ice storage barrel and a second opening communicated with the water receiving barrel;

the first opening is communicated with the ice outlet through an ice outlet pipeline.

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