CN219063837U

CN219063837U - Ice making device

Info

Publication number: CN219063837U
Application number: CN202320064133.XU
Authority: CN
Inventors: 傅峰峰; 何静子; 王建刚
Original assignee: Guangzhou Fugang Life Intelligent Technology Co Ltd
Current assignee: Guangzhou Fugang Life Intelligent Technology Co Ltd
Priority date: 2023-01-06
Filing date: 2023-01-06
Publication date: 2023-05-23
Anticipated expiration: 2033-01-06

Abstract

The utility model discloses an ice making device, which comprises a machine body, wherein an ice falling chamber is arranged on the machine body; the top end of the ice falling chamber is provided with an ice inlet; the bottom end of the ice falling chamber is provided with an ice outlet; the ice making assembly is used for making ice cubes, is arranged on the machine body and is positioned above the ice inlet so as to enable the ice cubes to fall into the ice inlet; the ice falling assembly is arranged in the ice falling chamber and comprises an ice guiding plate and an ice conveying mechanism, and the ice guiding plate is used for receiving ice prepared by the ice making assembly and guiding the ice to enter the ice conveying mechanism; the ice block conveying mechanism is used for conveying ice blocks to the ice outlet. The ice making device can make ice cubes through the ice making assembly, and then the ice cubes can be automatically output.

Description

Ice making device

Technical Field

The present utility model relates to an ice making apparatus.

Background

At present, when preparing cold drink, ice cubes or ice shaving and the like are generally directly placed in the drink, so that the drink has better taste. The common ice block is prepared by mainly introducing cold air prepared by a refrigerator into an ice making module, introducing water into the ice making module, freezing the water into ice blocks under the action of the cold air, and then taking out the ice blocks to be directly put into a drink or taking out the ice blocks to be made into sliced ice. However, the existing ice making method mainly relies on manual taking out of ice, and is low in automation degree.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model aims to provide an ice making device, which can make ice cubes through an ice making assembly and then automatically output the ice cubes.

The utility model adopts the following technical scheme:

an ice-making device, comprising,

the machine body is provided with an ice falling chamber; an ice inlet is formed in the top end of the ice falling chamber; the bottom end of the ice falling chamber is provided with an ice outlet;

the ice making assembly is used for making ice cubes, is arranged on the machine body and is positioned above the ice inlet so that the ice cubes fall to the ice inlet;

the ice falling assembly is arranged in the ice falling chamber and comprises an ice guiding plate and an ice conveying mechanism, and the ice guiding plate is used for receiving ice cubes prepared by the ice making assembly and guiding the ice cubes to enter the ice conveying mechanism; the ice conveying mechanism is used for conveying ice to the ice outlet.

Further, a water guide port is arranged at the bottom end of the ice falling chamber, and the water guide port is arranged below the ice conveying mechanism; the water guide port is communicated with a water guide pipe.

Further, the ice outlet is provided with a first ice outlet section and a second ice outlet section; the first ice outlet section and the second ice outlet section are sequentially distributed in the conveying direction of the ice block conveying mechanism;

the machine body is also provided with an ice shaving assembly and a push plate assembly, the push plate assembly comprises a push plate, the push plate can move along a pushing direction to be close to or far away from the first ice outlet section, and the push plate is used for blocking the first ice outlet section after moving close to the first ice outlet section;

the ice shaving assembly comprises a cutter disc, a cutter disc driving piece and a plurality of blades, and the cutter disc is rotatably arranged above the second ice outlet section; the cutter disc driving piece is used for driving the cutter disc to rotate; the plurality of blades are mounted on the cutterhead; the plurality of blades are used for cutting ice cubes on the push plate to form sliced ice.

Further, the ice shaving assembly further comprises an ice shaving chamber, wherein the ice shaving chamber is arranged above the second ice outlet section and communicated with the second ice outlet section; the side part of the ice shaving chamber is communicated with the ice falling chamber; the cutter head is rotatably arranged in the ice shaving chamber.

Further, the push plate assembly further comprises a push plate driving piece, the push plate driving piece comprises a push plate motor, a gear and a rack, a rotating shaft of the push plate motor is connected with the gear, and the rack is installed at the bottom end of the push plate and meshed with the gear.

Further, the ice block conveying mechanism comprises a spiral conveying rod and a conveying motor, wherein the spiral conveying rod is rotatably arranged at the bottom end of the ice falling chamber and is connected with the guiding tail end of the ice block guiding plate; the conveying motor is used for driving the spiral conveying rod to rotate;

the cutter head is provided with a rotating shaft, and the cutter head is synchronously connected with the cutter head driving piece through the rotating shaft; a through-connection cavity is arranged in the rotating shaft; the screw conveying rod is rotatably arranged in the cross-connection cavity through a bearing.

Further, the ice making assembly comprises a refrigerator, an ice making frame, a refrigerator, a water pipe and a cold air pipe, wherein the ice making frame is arranged above the ice inlet; an ice making opening is formed in the ice making frame, and an ice outlet plate is rotatably arranged in the ice making opening; the refrigerator is arranged above the ice outlet plate; the inner wall of the refrigerator is provided with a plurality of ice making grooves, and the bottom end of the refrigerator is communicated with the ice outlet plate; one end of the water pipe is communicated into the refrigerator; the other end of the water pipe is communicated with water supply equipment; one end of the cold air pipe is communicated with the refrigerator; the other end of the cold air pipe extends to the outer side of the refrigerator and is used for refrigerating the refrigerator.

The ice thickness detection sensor is arranged in the refrigerator and is used for detecting the ice thickness of the refrigerator.

Further, a bearing plate is arranged on the machine body, and the bearing plate is arranged below the ice outlet and is used for placing an external ice taking container; and a weighing mechanism is arranged on the bearing plate.

Compared with the prior art, the utility model has the beneficial effects that: when the ice making device is used for making ice, ice cubes can be made through the ice making assembly, the ice cubes made by the ice making assembly can fall into the ice falling chamber, and the ice cubes can be directly guided to the ice cube conveying mechanism to be carried out and output through the ice cube guiding plate, so that the ice cube output efficiency is higher, and the degree of automation is higher.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a cross-sectional view of the ice making assembly, ice chute assembly, and ice shaving assembly of the present utility model;

FIG. 3 is a cross-sectional view of the ice making assembly and ice chute assembly of the present utility model;

FIG. 4 is a cross-sectional view of the overall structure of the present utility model;

FIG. 5 is a schematic view of an ice shaving assembly and push plate assembly according to the present utility model;

fig. 6 is a schematic view of another embodiment of the present utility model.

In the figure: 11. a refrigerating machine; 12. an ice making frame; 13. preparing a refrigerator; 14. an ice discharging plate; 20. an ice falling chamber; 21. an ice outlet; 211. a first ice outlet section; 212. a second ice outlet section; 22. a water conduit; 31. an ice guide plate; 32. an ice delivery mechanism; 321. a conveying motor; 322. a screw conveyor rod; 323. a bearing; 33. an ice cube stirring mechanism; 40. an ice shaving assembly; 41. a cutterhead; 411. a rotating shaft; 42. a blade; 43. a push plate; 44. a push plate motor; 45. a gear; 46. a rack.

Detailed Description

The utility model will be further described with reference to the accompanying drawings and detailed description below:

in the description of the present utility model, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, merely to facilitate description of the present utility model and simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

An ice making device as shown in fig. 1-6 comprises a machine body, an ice making assembly and an ice falling assembly, wherein an ice falling chamber 20 is arranged on the machine body, an ice inlet is arranged at the top end of the ice falling chamber 20, and an ice outlet 21 is arranged at the bottom end of the ice falling chamber 20. The ice making assembly is used for preparing ice cubes, the ice making assembly can be arranged on the machine body, the ice making assembly can be positioned above the ice inlet, and the ice cubes prepared by the ice making assembly can fall into the ice inlet.

Install above-mentioned ice subassembly that falls in ice chamber 20, ice subassembly that falls includes ice-cube guide board 31, ice-cube conveying mechanism 32, with ice-cube guide board 31 installation in ice chamber 20 that falls, and ice-cube guide board 31 can receive the ice-cube that ice-cube assembly prepared, and ice-cube guide board 31 that ice-cube assembly prepared can fall to ice chamber 20 through the income ice mouth on ice-cube guide board 31, under ice-cube guide board 31's effect, guide ice-cube entering ice-cube conveying mechanism 32.

On the basis of the structure, when the ice making device is used, the ice making assembly on the machine body can be started, ice cubes can be made by the ice making assembly, the ice cubes made by ice can fall off and fall onto the ice cube guide plate 31 of the ice falling chamber 20 through the ice inlet of the ice falling chamber 20, under the action of the ice cube guide plate 31, the ice cubes can continuously enter the ice cube conveying mechanism 32, under the conveying action of the ice cube conveying mechanism 32, the ice cubes can fall out through the ice outlet 21 of the ice falling chamber 20, and a container for taking ice can be placed at the ice outlet 21. Further, a water guide may be provided at the bottom end of the ice-dropping chamber 20, and the water guide may be provided below the ice-conveying mechanism 32, and the water guide may be connected to the water guide pipe 22. Since the ice-dropping opening is in contact with air, ice cubes are easily melted at the ice-dropping opening near the ice-dropping chamber 20, and water is dropped from the ice-outlet 21 after being melted, a water outlet may be provided at the side of the ice-dropping opening, and a water guide pipe 22 may be connected to the water outlet for guiding the accumulated water to be led out.

Further, an ice shaving assembly 40 may be disposed on the machine body, in order to facilitate separate and export of the ice shaving and the ice cubes, the ice outlet 21 may be separated by a partition plate to form a first ice outlet section 211 and a second ice outlet section 212, specifically, the first ice outlet section 211 may directly receive the ice cubes conveyed by the ice cube conveying mechanism, the second ice outlet section 212 may be provided with the ice shaving assembly 40, and the ice shaving assembly 40 may cut the ice cubes of the second ice outlet section 212 to form ice shaving, that is, the second ice outlet section 212 may output the ice shaving, so, the ice cubes made by the ice making assembly in this embodiment may be exported via the first ice outlet section 211 or the second ice outlet section 212, respectively, and output the ice cubes or the ice shaving according to different requirements.

Specifically, the first ice discharging section 211 and the second ice discharging section 212 may be sequentially distributed in the conveying direction of the ice conveying mechanism, that is, when the ice conveying mechanism conveys ice, the ice conveying mechanism may firstly convey the ice to the first ice discharging section 211, and then convey the ice to the second ice discharging section 212 after passing through the first ice discharging section 211.

Specifically, the pushing plate assembly may include a pushing plate 43, where the pushing plate 43 may be moved in a pushing direction toward or away from the first ice discharging section 211, the pushing plate 43 may be used to block the first ice discharging section 211 after moving toward the first ice discharging section 211, and the pushing plate 43 may be used to open the first ice discharging section 211 after moving away from the first ice discharging section 211.

In addition, the ice shaving assembly 40 includes a cutter 41, a cutter driving member and a plurality of blades 42, wherein the cutter 41 is rotatably installed above the second ice outlet section 212; the cutter driving piece is used for driving the cutter 41 to rotate; the plurality of blades 42 are mounted on the cutterhead 41; the plurality of blades 42 are used to cut ice cubes on the push plate 43 to form sliced ice.

On the basis of the above-described structure, when the ice cubes are transported, the ice cubes made by the ice making assembly may be introduced into the ice falling chamber 20 through the ice inlet of the ice falling chamber 20, guided into the ice falling chamber 20 through the ice cube guide plate 31, and then transported to the ice outlet 21 through the ice cube transport mechanism 32.

When the ice cubes are needed, the pushing plate 43 can be driven by the pushing plate driving member to move away from the first ice discharging section 211, at this time, the first ice discharging section 211 can be opened, and the ice cubes can be directly discharged from the ice cube conveying mechanism 32 through the first ice discharging section 211.

When the ice shaving is needed, the push plate 43 can be driven by the push plate driving piece to be close to the first ice outlet section 211, the push plate 43 can be covered on the first ice outlet section 211, ice cubes can not fall off from the first ice outlet section 211 and are conveyed on the push plate 43, in the continuous conveying process of the ice cubes conveying mechanism 32, the ice cubes on the push plate 43 can be continuously conveyed to the second ice outlet section 212, the cutter disc 41 at the position of the second ice outlet section 212 rotates, when the ice cubes are pushed in, the cutter disc 41 can be contacted with the plurality of blades 42 on the cutter disc 41, the cutter blades 42 can cut the ice cubes when rotating, and the ice cubes are conveyed out from the second ice outlet section 212 after the ice shaving is formed.

Of course, on the basis of the structure without the push plate assembly, the cover plate can also be directly rotated at the position of the first ice outlet section 211, and when ice is required to be shaved, the cover plate can be rotated to cover the first ice outlet section 211.

Of course, the first ice discharging section 211 and the second ice discharging section 212 may be vertically distributed, the ice shaving assembly 40 may be movably disposed between the first ice discharging section 211 and the second ice discharging section 212, and when ice cubes are output, the ice shaving assembly 40 may be far away from the first ice discharging section 211 and the second ice discharging section 212 under the action of power such as a driving cylinder, so that the first ice discharging section 211 and the second ice discharging section 212 keep a vertically penetrating state, and the ice cubes are guided out through the first ice discharging section 211 and the second ice discharging section 212, and only need to be guided out from top to bottom. When the ice shaving is output, the ice shaving assembly 40 can be moved between the first ice outlet section 211 and the second ice outlet section 212, and the ice cubes guided out by the first ice outlet section 211 can be received by the ice shaving assembly 40, and then the ice cubes can be output by the second ice outlet section 212 after the ice shaving operation of the ice shaving assembly 40.

Further, the ice shaving assembly 40 further includes an ice shaving chamber, which may be disposed above the second ice outlet section 212, wherein a bottom end of the ice shaving chamber is communicated with the second ice outlet section 212, and a side portion of the ice shaving chamber is communicated with the first ice outlet section 211, so that after the ice conveying mechanism 32 conveys ice to the push plate 43 of the first ice outlet section 211, the ice shaving chamber may be introduced under a continuous action of a conveying force, and after an ice cutting action is performed in the ice shaving chamber, the ice is guided out from the bottom end of the ice shaving chamber to the second ice outlet section 212 and then is output.

Of course, on the basis of the structure that the first ice discharging section 211 and the second ice discharging section 212 are vertically distributed, openings are formed in the upper and lower sides of the ice shaving chamber for receiving the ice cubes introduced from the first ice discharging section 211 and guiding out the shaved ice. The ice shaving chamber can move under the action of power such as an external driving cylinder.

Further, the push plate assembly further comprises a push plate driving member, the push plate driving member comprises a push plate motor 44, a gear 45 and a rack 46, a rotating shaft of the push plate motor 44 is connected with the gear 45, the rack 46 is arranged at the bottom end of the push plate 43, the rack 46 can be meshed with the gear 45, the specific rack 46 can extend along the pushing direction, the pushing direction in the embodiment is the length direction of the push plate 43, when the push plate 43 is driven, the gear 45 can be driven to rotate through the push plate motor 44, and the rack 46 meshed with the gear 45 can be driven to move back and forth through rotation of the gear 45, so that the push plate 43 is moved.

Of course, the push plate driving member can be realized by adopting a linear motion output structure such as a screw rod transmission mechanism or an air cylinder in the prior art.

Further, the ice conveying mechanism 32 in this embodiment includes a screw conveying rod 322 and a conveying motor 321, the screw conveying rod 322 is rotatably mounted at the bottom end of the ice falling chamber 20, the screw conveying rod 322 can be connected to the guiding end of the ice guiding plate 31, and the conveying motor 321 is used for driving the screw conveying rod 322 to rotate. When the ice cubes are output, the screw conveying rod 322 can be driven to rotate through the conveying motor 321, and the screw conveying rod 322 can be guided to be led out through the screw blades of the screw conveying rod 322 by rotation of the screw conveying rod 322, so that the ice cubes are output. And the speed of ice falling is realized by controlling the rotation speed of the conveying motor 321, so that the requirement of rapidly falling ice during beverage making is met.

On the basis of the structure, a rotating shaft 411 is arranged on the cutter 41, the cutter 41 is synchronously connected with a cutter driving piece through the rotating shaft 411, on the basis of the structure that the cutter driving piece is a motor, the rotating shaft of the motor can be synchronously connected with the rotating shaft 411 of the cutter 41 through a belt transmission mechanism, namely, the rotation of the motor can be transmitted through the belt transmission mechanism, so that the rotation of the cutter 41 is realized.

Specifically, a through-connection cavity may be disposed in the rotation shaft 411, and the screw conveying rod 322 is rotatably mounted in the through-connection cavity through the bearing 323, so that the screw conveying rod 322 and the cutter 41 can be coaxially mounted in rotation, but the screw conveying rod 322 and the rotation shaft 411 of the cutter 41 are rotatably connected through the bearing 323, that is, the screw conveying rod 322 and the cutter 41 can also rotate independently without interference.

Further, the ice making assembly in this embodiment includes a refrigerator 11, an ice making frame 12, a refrigerator 13, a water pipe and a cold air pipe, the ice making frame 12 is installed above the ice inlet, the ice making frame 12 is provided with an ice making port, and an ice outlet plate 14 is rotatably arranged in the ice making port.

The refrigerator 13 is arranged above the ice outlet plate 14, a plurality of ice making grooves are arranged on the inner wall of the refrigerator 13, and the bottom end of the refrigerator 13 penetrates through the ice outlet plate 14. One end of the water pipe is communicated into the refrigerator 13; the other end of the water pipe is communicated with water supply equipment; one end of the cold air pipe is communicated with the refrigerator 11; the other end of the cold air pipe extends to the outside of the refrigerator 13 and is used for refrigerating the refrigerator 13.

On the basis of the above structure, when ice making operation is performed, water can be introduced into the refrigerator 13 through the water pipe, meanwhile, cool air produced by the refrigerator 11 can be introduced into the refrigerator 13 through the cool air pipe, the water in the refrigerator 13 is frozen, ice cubes can be formed in the plurality of ice making grooves by the frozen water, and after the ice cubes are made, the introduction operation of the refrigerator 11 and the water pipe can be stopped. Then, the ice cubes can drop onto the ice outlet plate 14 through the bottom end of the refrigerator 13 under the action of dead weight, and the ice outlet plate 14 is rotatably arranged at the ice making opening, so that the ice cube gravity can rotate the ice outlet plate 14 under the condition that the ice cubes on the ice outlet plate 14 are heavy enough, and the ice cubes can drop into the ice inlet of the ice falling chamber 20 through the ice making opening, so that the automatic guiding and receiving of the ice cubes are realized.

It should be noted that the refrigerator 11 may be formed by a refrigeration device in the prior art, and the specific refrigeration structure and the working principle are not protected in the present application, so that detailed descriptions thereof are omitted herein.

Further, an ice thickness detecting sensor may be further disposed in the refrigerator 13, and the specific ice thickness detecting sensor may detect the ice thickness of the refrigerator 13, so, when ice is made, the ice thickness detecting sensor may detect the ice thickness in the refrigerator 13, and control the start and stop of the refrigerator 11 according to the ice thickness, so that the ice thickness may be adjusted as required.

Further, the machine body in this embodiment is provided with a supporting plate, the supporting plate is arranged below the ice outlet 21, the supporting plate can be used for placing an external ice taking container, and a weighing mechanism is arranged on the supporting plate, so that when ice is taken, the supporting plate can be provided with the ice taking container such as a cup, ice cubes can be conveyed to the ice outlet 21 through the ice cube conveying mechanism 32, the ice cubes can directly fall into the ice taking container through the ice outlet 21, in the ice taking process, an operator can obtain the weight of the ice cubes through the weighing mechanism, and the ice taking amount can be controlled according to the weight of the ice cubes.

Further, referring to fig. 6, in the present embodiment, an ice stirring mechanism 33 may be provided in the ice dropping chamber 20, and the ice conveying mechanism may convey ice to the ice outlet 21, and in this process, the ice stirring mechanism 33 may break up ice on the ice guide plate 31.

When the ice cubes made by the ice making assembly gradually drop, the ice outlet 21 is insufficient in ice outlet speed, ice cubes are easily accumulated on the ice cube guide plate 31 and are easily accumulated during conveying, the ice cubes are easily accumulated to be overhead, the ice cubes cannot be dropped, namely, the ice cubes cannot enter the ice cube conveying mechanism 32, the ice cube conveying mechanism 32 is invalid in work, and therefore the ice cubes can be broken up before being output through the ice cube stirring mechanism 33 arranged on the ice cube guide plate 31, the ice cubes cannot be accumulated and overhead, the ice cube output efficiency is higher, and the degree of automation is higher.

The ice stirring mechanism 33 comprises a stirring shaft and a plurality of stirring rods, wherein two ends of the stirring shaft are rotatably arranged on two side walls of the ice falling chamber 20; the stirring rods are distributed at intervals in the axial direction of the stirring rods; the stirring rods are distributed in a staggered manner at intervals on the circumference of the stirring shaft, so that the stirring rods can be connected with the rotating shaft of the conveying motor 321 through the transmission mechanism, the conveying motor 321 can drive the stirring shaft to rotate when the conveying motor 321 acts, the stirring shaft can rotate to drive the stirring rods on the stirring shaft to rotate, and the stirring shafts can break up ice cakes in the circumference and the axial direction, so that the effect is better.

It will be apparent to those skilled in the art from this disclosure that various other changes and modifications can be made which are within the scope of the utility model as defined in the appended claims.

Claims

1. An ice making apparatus, comprising,

2. The ice making apparatus of claim 1, wherein said ice outlet has a first ice outlet section and a second ice outlet section; the first ice outlet section is used for receiving the ice cubes conveyed by the ice cube conveying mechanism and outputting the ice cubes; the second ice outlet section is provided with an ice shaving assembly and is used for receiving ice cubes conveyed by the ice cube conveying mechanism; the ice shaving assembly is used for cutting the ice cubes so that the second ice outlet section outputs the shaved ice.

3. The ice making apparatus of claim 2, wherein said first ice-out section and said second ice-out section are distributed in a conveying direction of said ice-cake conveying mechanism;

the machine body is also provided with a push plate assembly, the push plate assembly comprises a push plate, the push plate can move along a pushing direction to be close to or far away from the first ice outlet section, and the push plate is used for blocking the first ice outlet section after moving close to the first ice outlet section;

4. The ice making apparatus of claim 3, wherein said ice shaving assembly further comprises an ice shaving chamber disposed above and in communication with said second ice discharge section; the side part of the ice shaving chamber is communicated with the ice falling chamber; the cutter head is rotatably arranged in the ice shaving chamber.

5. The ice making apparatus of claim 3, wherein the push plate assembly further comprises a push plate driving member including a push plate motor, a gear, and a rack, a rotation shaft of the push plate motor being connected to the gear, the rack being mounted to a bottom end of the push plate and engaged with the gear.

6. The ice-making device of claim 3, wherein said ice-cube conveying mechanism comprises a screw conveyor bar rotatably mounted to a bottom end of said ice-drop chamber and engaged with a leading end of said ice-cube guide plate, and a conveyor motor; the conveying motor is used for driving the spiral conveying rod to rotate;

7. The ice-making device according to any one of claims 1 to 6, wherein the ice-making assembly comprises a refrigerator, an ice-making frame installed above the ice inlet, a refrigerator, a water pipe, and a cold air pipe; an ice making opening is formed in the ice making frame, and an ice outlet plate is rotatably arranged in the ice making opening; the refrigerator is arranged above the ice outlet plate; the inner wall of the refrigerator is provided with a plurality of ice making grooves, and the bottom end of the refrigerator is communicated with the ice outlet plate; one end of the water pipe is communicated into the refrigerator; the other end of the water pipe is communicated with water supply equipment; one end of the cold air pipe is communicated with the refrigerator; the other end of the cold air pipe extends to the outer side of the refrigerator and is used for refrigerating the refrigerator.

8. The ice-making device as recited in claim 7, wherein an ice-thickness detecting sensor is provided in the ice-making chamber, and the ice-thickness detecting sensor is configured to detect an ice thickness of the ice-making chamber.

9. The ice making apparatus according to any one of claims 1 to 6, wherein a support plate is provided on said body, said support plate being provided below said ice outlet and being for placing an external ice taking container; and a weighing mechanism is arranged on the bearing plate.

10. The ice making apparatus according to any one of claims 1 to 6, wherein an ice stirring mechanism is further provided in the ice falling chamber, the ice stirring mechanism being provided above the ice conveying mechanism; the ice block stirring mechanism comprises a stirring shaft and a plurality of stirring rods, and two ends of the stirring shaft are rotatably arranged on two side walls of the ice falling chamber; the stirring rods are scattered and distributed at intervals in the axial direction of the stirring rods; the stirring rods are distributed in a staggered manner at intervals in the circumferential direction of the stirring shaft.