CN114608236A - Intelligent quantitative ice cake and smoothie feeding device - Google Patents

Abstract

The invention discloses an intelligent quantitative ice cake and ice sediment feeding device, which relates to the technical field of ice sediment makers and comprises an ice storage tank, an ice cake conveying mechanism, an ice cake feeding mechanism and an automatic ice sediment machine, wherein an ice cake outlet is formed in the lower side of the ice storage tank, the automatic ice sediment machine is positioned above the ice storage tank, the automatic ice sediment machine is provided with an ice cake inlet, the first end of the ice cake conveying mechanism is close to the ice cake outlet, the second end of the ice cake conveying mechanism is close to the ice cake inlet, and the ice cake feeding mechanism is close to the ice cake inlet. The ice conveying mechanism and the ice feeding mechanism convey ice in the ice storage tank to the automatic ice slush machine, and the whole process is in zero contact with personnel, so that the sanitation and safety of eating ice are ensured.

Description

Intelligent quantitative ice cake and smoothie feeding device

Technical Field

The invention relates to the technical field of ice-slush makers, in particular to an intelligent quantitative feeding device for ice-cube ice-slush.

Background

The existing ice machine only has the ice crushing step which is automatic program control operation, but the ice block input and the ice sand pouring are both manual operation, time and labor are wasted, and misoperation is easy to occur during manual ice feeding, so that the sanitation potential hazards and the safety potential hazards are caused. Meanwhile, the existing ice machine cannot realize automatic closed-loop control of the whole process, so that ice cubes are not directly put into ice-making after being taken out of an ice maker or an ice storage device, the placing time of the ice cubes cannot be mastered, the contact time with air is too long, and the change of microbial environments such as escherichia coli is easy to breed.

The ice blocks of the existing ice-sand machine are put into manual operation, and if accurate and quantitative ice-sand making is to be realized, the manual weighing operation is needed before the feeding after the ice blocks are taken. Therefore, the manual operation link is increased, the total working hours for making the ice sand are prolonged, and the working efficiency is sacrificed for ensuring the product quality. After the ice slush is manufactured, the situation that the discharging is not accurate, the ice slush is remained and the material is wasted exists in manual material pouring.

Disclosure of Invention

Therefore, the invention provides an intelligent quantitative ice cube and ice slush feeding device, which aims to solve the problems that in the prior art, the operation is time-consuming and labor-consuming due to the fact that ice cubes are manually put in, and the potential health hazard and the potential safety hazard are caused due to the fact that misoperation is easy to occur.

In order to achieve the above purpose, the invention provides the following technical scheme:

the utility model provides an ice-cube ice-cake husky intelligence quantitative feedway, including storing the ice tank, ice-cube conveying mechanism, the ice-cube throws material mechanism and automatic ice-cube machine, it is equipped with the ice-cube export to store the ice tank downside, it has automatic ice mechanism to go out to store ice inslot portion, automatic ice-cube machine is located and stores the ice tank top, automatic ice-cube machine has the ice-cube entry, ice-cube conveying mechanism's first end is close to the ice-cube export, ice-cube conveying mechanism's second end is close to the ice-cube entry, the ice-cube throws material mechanism and is close to the ice-cube entry.

Further, automatic go out ice mechanism and include the heat preservation casing, quantitative ejection of compact flood dragon screw rod, ice-cube ration ejection of compact motor and ice-cube ejection of compact guide mouth are located the heat preservation casing, ice-cube ration ejection of compact motor and quantitative ejection of compact flood dragon screw rod drive are connected, ice-cube ejection of compact guide mouth is located quantitative ejection of compact flood dragon screw rod end, the ice-cube export of ice-storage tank downside is ice-cube ejection of compact guide mouth.

Furthermore, the automatic ice discharging mechanism also comprises a control unit which is electrically connected with an ice quantitative discharging motor.

Further, piece transport mechanism includes slide rail, ice-cube and carries driving motor and ice-cube ration mechanism, and the first end of slide rail is close to the ice-cube export, and the second end of slide rail is close to the ice-cube entry, and ice-cube ration mechanism and slide rail sliding connection, ice-cube ration mechanism include ice hopper and weighing sensor, and the ice hopper below is equipped with weighing sensor, ice hopper and slide rail sliding connection.

Furthermore, the ice hopper is connected with the ice block conveying sliding table assembly in a turnover mode, the ice block conveying sliding table assembly is connected with the sliding rail in a sliding mode, the ice block feeding mechanism is provided with an ice block stirring assembly, and the ice block stirring assembly is close to an ice block inlet.

Furthermore, the automatic ice-sand maker is provided with a layer of ice inlet and a layer of ice inlet, the ice feeding mechanism is provided with a slide rail, an avoiding motor mounting frame, an avoiding motor and two ice shifting assemblies, the two ice shifting assemblies are respectively close to the ice inlet, and the slide rail, the avoiding motor mounting frame and the avoiding motor are positioned between the layer of ice inlet and the layer of ice inlet.

Furthermore, the automatic ice slush machine comprises an ice pressing piston, a screw rod, an ice cutting motor and a blade, the ice pressing piston moves up and down through the screw rod, the blade is arranged below the ice pressing piston and is in transmission connection with the ice cutting motor, the ice pressing piston and the blade are positioned between the inlet of the ice block layer and the inlet of the ice block layer, the ice slush guide port is positioned below the blade, and the ice slush guide port is also communicated with the inlet of the ice block layer.

The invention has the following advantages: the ice conveying mechanism and the ice feeding mechanism convey ice in the ice storage tank to the automatic ice and sand machine, and personnel are in zero contact in the whole process, so that the sanitation and safety of eating the ice are ensured.

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 description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so that those skilled in the art can understand and read the present invention, and do not limit the conditions for implementing the present invention, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the functions and purposes of the present invention, should still fall within the scope covered by the contents disclosed in the present invention.

FIG. 1 is a front view of an intelligent quantitative ice cube smoothie feeding device according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an intelligent quantitative ice cube smoothie feeding device according to an embodiment of the present invention;

FIG. 3 is a top view of an intelligent quantitative ice cube smoothie feeding device according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of the internal structure of an automatic ice machine of an intelligent quantitative ice cube ice feeding device according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a rubber mat assembly of an ice cube smoothie intelligent quantitative supply device according to an embodiment of the present invention.

In the figure: 1-an ice storage tank; 2-automatic ice discharging mechanism; 3-an ice cube dosing mechanism; 4-an ice block transport mechanism; 5-an ice block feeding mechanism; 6-automatic sand-freezing machine; 2.4-ice block discharging guide port; 3.1-ice bucket; 3.2-weighing sensor; 4.1-sliding rail; 4.2-ice conveying driving motor; 5.1-a layer of ice block kickoff assembly; 5.2-sliding rail; 5.3-avoiding the motor mounting rack; 5.4-avoiding motor; 5.5-two layers of ice block material stirring components; 6.1-upper cover; 6.2-ice pressing component; 6.3-ice cutting assembly; 6.4-ice dropping assembly; 6.5-rubber mat component; 6.7-one layer ice inlet; 6.6-two-layer ice inlet; 6.2.1-pressing the ice shell; 6.2.2-lead screw; 6.2.3-pressing ice piston; 6.2.4-ice pressing motor; 6.2.5-two-layer ice inlet plate; 6.3.1-integral structural member of the inner cavity of the shell; 6.3.2-ice cutting motor; 6.3.3-cutter head mounting piece; 6.3.4-blade; 6.4.1-shell; 6.4.2-a layer of ice block inlet plate, 6.4.3-a guide port for discharging ice sand; 6.5.1-rubber pad; 6.5.2-Lock Accessories.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the present specification, the terms "upper", "lower", "left", "right", "middle", and the like are used for clarity of description, and are not intended to limit the scope of the present invention, and changes or modifications in the relative relationship may be made without substantial changes in the technical content.

As shown in fig. 1, the specific embodiment of the present invention provides an intelligent quantitative feeding device for ice cubes and ice cubes, comprising an ice storage tank 1, an ice cube conveying mechanism 4, an ice cube feeding mechanism 5 and an automatic ice cube maker 6, wherein an ice cube outlet is arranged at the lower side of the ice storage tank 1, the automatic ice cube maker 6 is located above the ice storage tank 1, the automatic ice cube maker 6 has an ice cube inlet, a first end of the ice cube conveying mechanism 4 is close to the ice cube outlet, a second end of the ice cube conveying mechanism 4 is close to the ice cube inlet, and the ice cube feeding mechanism 5 is close to the ice cube inlet. The ice conveying mechanism 4 and the ice feeding mechanism 5 convey ice in the ice storage tank 1 to the automatic ice and sand machine 6, and the automatic mechanical device and the control system are adopted to realize full process automation, so that the whole process is in zero contact with personnel, and the safety and the sanitation of edible ice are ensured.

In an optional embodiment, ice storage tank 1 is inside to have automatic ice mechanism 2 that goes out, automatic ice mechanism 2 that goes out includes the heat preservation casing, quantitative ejection of compact flood dragon screw rod, ice-cube quantitative ejection of compact motor and ice-cube ejection of compact guide slot are located the heat preservation casing, ice-cube quantitative ejection of compact motor and quantitative ejection of compact flood dragon screw rod drive are connected, ice-cube ejection of compact guide slot 2.4 is located quantitative ejection of compact flood dragon screw rod end, the ice-cube export of ice storage tank 1 downside is ice-cube ejection of compact guide slot 2.4. The screw conveying mode is adopted, and the ice cube conveying mechanism is compatible with ice cubes in different shapes, such as square ice, semi-ice, cylindrical ice, crushed ice and the like.

The automatic ice discharging mechanism 2 further comprises a control unit, the control unit is a PLC, a single chip microcomputer or an industrial personal computer, at the moment, according to the work order requirement, the control unit drives an ice block quantitative discharging motor, and a quantitative discharging screw is driven by the motor to realize the forward movement of the ice block. The quantitative discharging screw conveys ice cubes to the ice cube discharging guide opening 2.4 and the ice cubes fall into the ice cube quantitative mechanism 3 through the ice cube discharging guide opening 2.4. While the quantitative discharging auger screw forwards conveys the ice cubes, the inclined surface necking stainless steel inner container in the ice storage tank 1 continuously guides the ice cubes to slide and guide the ice cubes to the quantitative discharging auger screw. The ice block allowance is calculated through a PLC, a single chip microcomputer or an industrial personal computer. When the ice block residue drops to the feed water level, a feed notice is automatically sent. After the personnel finish the feed supplement operation, the system automatically finishes the ice block full water level reset, and can monitor the ice block usage amount and the ice block surplus in real time.

In an alternative embodiment, as shown in fig. 2, the ice conveying mechanism 4 includes a slide rail 4.1, an ice conveying driving motor 4.2, and an ice dosing mechanism 3, a first end of the slide rail 4.1 is close to the ice outlet, a second end of the slide rail 4.1 is close to the ice inlet, the ice dosing mechanism 3 is slidably connected to the slide rail 4.1, the ice dosing mechanism 3 includes an ice bucket 3.1 and a weighing sensor 3.2, the weighing sensor 3.2 is disposed below the ice bucket 3.1, and the ice bucket 3.1 is slidably connected to the slide rail 4.1.

Quantitative ejection of compact flood dragon screw rod carries the ice-cube to ice-cube ejection of compact guide port 2.4, falls into ice-cube ejection of compact guide port 2.4 in the middle of ice-cube ejection of compact guide port 3.1, and weighing sensor 3.2 that is located ice-cube 3.1 below acquires ice-cube weight in real time to send PLC, singlechip or industrial computer, when reaching target weight, stop ice-cube quantitative ejection of compact motor. Meanwhile, the ice cube weight data is stored and accumulated by a PLC, a single chip microcomputer or an industrial personal computer, or is sent to an upper computer through the Internet of things/the Internet and stored and accumulated by the upper computer.

In an alternative embodiment, as shown in fig. 2, the ice hopper 3.1 is reversibly connected to the ice delivery chute assembly, the ice delivery chute assembly is slidably connected to the slide rail 4.1, and the ice feeding mechanism 5 has an ice ejecting assembly, which is adjacent to the ice inlet.

The conveying sliding table conveys the ice bucket 3.1 fully loaded with ice blocks to the ice block inlet, the ice block stirring assembly overturns the ice bucket 3.1, the ice blocks slide into the ice block inlet, and the ice blocks are directly thrown into a container for producing ice blocks or ice slush. The ice block kickoff assembly is a mechanical mechanism, the ice block conveying sliding table assembly 4.1 continuously moves in the process of feeding ice blocks in the ice hopper 3.1 overturning process until the ice blocks touch the photoelectric sensor, the ice block conveying driving motor 4.2 brakes, stops moving and enables the ice hopper 3.1 to overturn back to the initial position, the ice hopper 3.1 is descended back to the position below the ice block discharging guide port 2.4 and is the initial position of the ice block conveying mechanism 4

In an alternative embodiment, as shown in fig. 2 and 3, the automatic ice slush machine 6 has a one-layer ice inlet 6.7 and a two-layer ice inlet 6.6, the ice feeding mechanism 5 has two ice-ejecting assemblies, a slide rail 5.2, a bypass motor mounting bracket 5.3, and a bypass motor 5.4, the two ice-ejecting assemblies are respectively adjacent to the one-layer ice inlet, and the slide rail 5.2, the bypass motor mounting bracket 5.3, and the bypass motor 5.4 are located between the one-layer ice inlet 6.7 and the two-layer ice inlet 6.6.

The design of the system is compatible with two functions of quantitative feeding of ice blocks and instant making and quantitative feeding of ice slush. The automatic ice and sand machine 6 is divided into a first layer ice inlet 6.7 and a second layer ice inlet 6.6.

If the order demand is ice blocks, the ice block conveying mechanism 4 conveys the ice hopper 3.1 fully loaded with the ice blocks to the position of an ice block inlet 6.7, the ice hopper is turned over by the ice block stirring assembly 5.1, the ice blocks slide to the ice block inlet 6.7, and the ice blocks are directly thrown into an ice block production container.

Because the two layers of ice block inlets are positioned on the same vertical plane, if the order demand is ice sand, before the ice blocks are quantitatively discharged, the avoiding motor drives the one layer of ice block stirring assembly to move to the tail end of the sliding rail, and the avoiding ice block conveying sliding table assembly rises to the position of the two layers of ice block inlets 6.6. The ice conveying sliding table assembly conveys ice fully loaded with ice to the position of the two-layer ice inlet 6.6, the two-layer ice stirring assembly 5.5 overturns the ice hopper 3.1, the ice slides to the two-layer ice inlet 6.6, and the ice is thrown into a container for producing ice slush.

In an alternative embodiment, as shown in fig. 4, the automatic ice slush machine 6 comprises an ice pressing piston 6.2.3, a screw rod 6.2.2, an ice cutting motor 6.3.2 and a blade 6.3.4, wherein the ice pressing piston 6.2.3 moves up and down through the screw rod 6.2.2, the blade 6.3.4 is arranged below the ice pressing piston 6.2.3, the blade 6.3.4 is in transmission connection with the ice cutting motor 6.3.2, the ice pressing piston 6.2.3 and the blade 6.3.4 are positioned between the one-layer ice cube inlet 6.7 and the two-layer ice cube inlet 6.6, the ice slush guide port 6.4.3 is positioned below the blade 6.3.4, and the ice slush guide port 6.4.3 is also communicated with the one-layer ice cube inlet 6.7. Before the ice cubes are fed, the ice pressing piston is in the initial position, namely the top of the screw rod. The ice is fed through the two-layer ice inlet 6.6 and falls into the inner cavity of the ice-cutting assembly. The system drives an ice pressing motor, and an ice pressing piston is driven by a screw rod to press an ice block; meanwhile, the ice cutting motor is driven to drive the blade to rotate at a high speed to cut ice. The ice sand falls into the production container through the ice sand outlet guide port. The ice pressing piston moves to the bottom of the screw rod to cut ice blocks, the ice cutting motor stops working, and the ice pressing piston returns to the initial position.

Specifically, the automatic ice slush machine is composed of an upper cover 6.1, an ice pressing assembly 6.2, an ice cutting assembly 6.3, an ice falling assembly 6.4 and a rubber pad assembly 6.5.

The ice pressing assembly 6.2 comprises a screw rod 6.2.2, an ice pressing piston 6.2.3, an ice pressing motor 6.2.4 and a double-layer ice inlet plate 6.2.5 which are positioned inside an ice pressing shell 6.2.1.

The ice cutting assembly 6.3 consists of a shell inner cavity integrated structural member 6.3.1, an ice cutting motor 6.3.2, a cutter disc mounting member 6.3.3 and blades 6.3.4.

The ice dropping assembly 6.4 consists of a housing 6.4.1, a layer of ice inlet plate 6.4.2, and a slush outlet guide 6.4.3.

As shown in fig. 5, the rubber pad assembly 6.5 is composed of a rubber pad 6.5.1 and a locking member 6.5.2.

The ice block discharging guide port, the ice port, the inner cavity of the ice slush machine, the ice pressing mechanism and other main mechanism parts adopt a plastic injection molding process, and structural parts with complex structures, multiple curved surfaces and easy disassembly and assembly can be rapidly produced in large quantities. All plastic parts in contact with the ice blocks are made of food-grade plastics, and metal parts in contact with the ice blocks are made of food-grade stainless steel 304, so that the sanitation and safety of eating the ice blocks are guaranteed. The electric elements of the device are all coated and locked by the plastic shell, and even if the personnel improperly operate and wash residual moisture in the parts, the personnel does not contact the electric elements, thereby protecting the safety of the personnel and the equipment.

In the mechanical device, plastic parts needing frequent disassembly and cleaning are designed without screws, the quick disassembly and assembly of the part assembly are realized by the modes of buckling, sliding grooves, bosses, feet and the like of the structure, personnel can realize the disassembly and assembly without using any tool, and the operation is simple and convenient.

The system has self-induction capability and can automatically monitor the ice block allowance in real time. The total weight of the full water level of the ice storage blocks in the ice storage tank 1 can be preset in a database of the system according to the actual volume of the stainless steel inner container or the operation requirement, and the low water level of the ice blocks is preset at the same time. The system receives the work order requirement sent by the upper computer, and the work order contains the triggering execution reality, the weight of ice blocks, ice blocks or ice sand and the information of ice block types. The system firstly judges whether the ice block allowance accumulated and subtracted in the ice storage tank 1 meets the ice block requirement weight of the work order, the work order can be executed only if the ice block allowance meets the ice block requirement weight, a material shortage alarm is automatically sent out if the ice block allowance does not meet the ice block requirement weight, and the work order is not executed.

The system automatically cuts ice block conveying times according to the preset capacity of the ice hopper, and simultaneously drives the ice block quantitative discharging motor to automatically discharge ice. The weighing sensor below the ice bucket acquires the actual weight of ice at each time, and the system automatically deducts the actual weight of the ice in real time. When remaining ice volume equals or is less than ice-storage tank 1 ice-cube low water level, the automatic delivery feed supplement of this system is notified, shows the feed supplement in ice-storage tank 1's human-computer interface and notifies to the host computer, on being notified monitor interface or cell-phone APP by the host computer, realizes the automatic ration ejection of compact of ice-cube, can be according to single-stroke order demand to actual ice-cube weighing control ejection of compact motor.

The automatic ice slush machine 6 is in full automation of feeding and making of ice cubes, the ice pressing motor drives the ice pressing piston to press the ice cubes, the ice cutting motor drives the rotary blade, and meanwhile, high-speed automatic making of the ice slush is achieved through operation. The cutter head of the automatic ice and sand machine 6 can manually adjust the installation height of the blades, ice and sand with different granularity can be cut according to the size of the gap between the blades and the cutter head, meanwhile, the speed of the ice pressing motor and the speed of the ice cutting motor can be adjusted, and the ice and sand with various granularity can be manufactured by matching with the installation height of the blades.

The device of the invention reserves the installation position of the circuit board, and can write the control program into the circuit board, so that the device becomes a standard product. The connector of the device can also independently link each electric element to a plurality of relays, the programmable logic controller independently controls the power on and off to realize the start-stop control, and the function characteristics of individual customization are realized by controlling the change of program time parameters. The intelligent equipment can be embedded into an intelligent equipment frame as a standard module for use, and can also be used as independent equipment for independent commercial popularization.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (7)

1. The utility model provides an ice cube ice sand intelligence ration feedway which characterized in that: throw material mechanism (5) and automatic ice machine (6) including ice storage tank (1), automatic ice mechanism (2), ice-cube conveying mechanism (4), ice-cube, ice storage tank (1) downside is equipped with the ice-cube export, ice storage tank (1) is inside to be had automatic ice mechanism (2) of going out, automatic ice machine (6) are located ice storage tank (1) top, automatic ice machine (6) have the ice-cube entry, the first end of ice-cube conveying mechanism (4) is close to the ice-cube export, the second end of ice-cube conveying mechanism (4) is close to the ice-cube entry, the ice-cube is thrown material mechanism (5) and is close to the ice-cube entry.

2. The intelligent ice cube smoothie quantitative feeding device of claim 1, wherein: automatic go out ice mechanism (2) including heat preservation casing, quantitative ejection of compact flood dragon screw rod, ice-cube ration ejection of compact motor and ice-cube ejection of compact guide (2.4), quantitative ejection of compact flood dragon screw rod ice-cube ration ejection of compact motor with ice-cube ejection of compact guide (2.4) are located in the heat preservation casing, ice-cube ration ejection of compact motor with quantitative ejection of compact flood dragon screw rod drive connects, ice-cube ejection of compact guide (2.4) are located quantitative ejection of compact flood dragon screw rod is terminal, ice-cube outlet department is ice-cube ejection of compact guide (2.4).

3. The intelligent ice cube smoothie dosing device of claim 2, wherein: the automatic ice discharging mechanism (2) further comprises a control unit, and the control unit is electrically connected with the ice quantitative discharging motor.

4. The intelligent ice cube smoothie quantitative feeding device of claim 1, wherein: ice-cube conveying mechanism (4) include slide rail (4.1), ice-cube transport driving motor (4.2) and ice-cube dosing mechanism (3), the first end of slide rail (4.1) is close to the ice-cube export, the second end of slide rail (4.1) is close to the ice-cube entry, ice-cube dosing mechanism (3) with slide rail (4.1) sliding connection, ice-cube dosing mechanism (3) are including ice fill (3.1) and weighing sensor (3.2), ice fill (3.1) below is equipped with weighing sensor (3.2), ice fill (3.1) with slide rail (4.1) sliding connection.

5. The intelligent ice cube smoothie dosing device of claim 4, wherein: ice hopper (3.1) connect the ice-cube with overturning and carry the slip table subassembly, the ice-cube is carried slip table subassembly and slide rail (4.1) sliding connection, the ice-cube throws material mechanism (5) and has the ice-cube and dials the material subassembly, the ice-cube is dialled the material subassembly and is close to the ice-cube entry.

6. The intelligent ice cube smoothie dosing device of claim 5, wherein: automatic ice sand machine (6) have one deck ice-cube entry (6.7) and two layers of ice-cubes entry (6.6), ice-cube throws material mechanism (5) slide rail (5.2), dodge motor mounting bracket (5.3), dodge motor (5.4) and two ice-cubes and dial the material subassembly, two the ice-cube is dialled the material subassembly and is close to one respectively the ice-cube entry, slide rail (5.2) dodge motor mounting bracket (5.3) with dodge motor (5.4) and be located one deck ice-cube entry (6.7) with between two layers of ice-cube entry (6.6).

7. The intelligent ice cube smoothie dosing device of claim 6, wherein: automatic ice sand machine (6) are including pressing ice piston (6.2.3), lead screw (6.2.2), cutting ice motor (6.3.2) and blade (6.3.4), press ice piston (6.2.3) to pass through lead screw (6.2.2) reciprocate, press ice piston (6.2.3) below to be equipped with blade (6.3.4), blade (6.3.4) with cutting ice motor (6.3.2) transmission is connected, press ice piston (6.2.3) with blade (6.3.4) are located one deck ice-cube entry (6.7) with between two layers of ice-cube entry (6.6), ice sand guide opening (6.4.3) are located blade (6.3.4) below, ice sand guide opening (6.4.3) still with one deck ice-cube entry (6.7) intercommunication.

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