CN111879050A - Full-automatic continuous vacuum cooling device and method applying same - Google Patents

Abstract

The application relates to the technical field of cold chains, in particular to a full-automatic continuous vacuum cooling device and a method applying the device, wherein the common technical points of the two schemes are as follows: the food to be cooled is placed on the conveying mechanism, the material to be cooled is transferred by the conveying mechanism, the material to be cooled is placed into the box body through the feeding hole, then the box body is isolated from the outside under the action of the sealing assembly, the independent placing and sealing of the material to be cooled are realized, the sealed material is cooled and processed through the cooling mechanism, the cooling time in the box body is preset, after the cooling time is finished, the material to be cooled and processed is forcedly pushed out through the material to be cooled by the discharging hole, the pushed-out cooled material is carried by the conveying mechanism, and then the cooled material is output through the conveying mechanism. The cooling device has the advantages of small occupied area, high cooling speed and realization of automatic uninterrupted continuous production.

Description

Full-automatic continuous vacuum cooling device and method applying same

Technical Field

The present application relates to the field of cold chain technology, and more particularly, to a fully automatic continuous vacuum cooling apparatus and a method for using the same.

Background

The food cold chain is established along with the progress of science and technology and the development of refrigeration technology, and is a logistics phenomenon under the condition of low temperature on the basis of refrigeration technology and by means of refrigeration technology. The construction of the cold chain therefore requires the centralized consideration of the various production, transportation, marketing, economic and technical problems involved, coordinating the relationships with each other to ensure the safety of perishable foods during processing, transportation and marketing, a cryogenic system project with a high technological content.

Wherein the cooling processing to food is one of indispensable links in the food cold chain, and traditional cooling methods have indoor beach cooling, forced cooling storehouse ventilation cooling, air conditioner intercooling and instant freezer cooling etc. but this kind of traditional cooling has many drawbacks, for example: long cooling time, large occupied space and other problems.

With the continuous development of modern technology, more and more production equipment tends to be in automatic production so as to realize portable operation instead of manual work, so that how to realize automatic processing production of food cooling is a problem to be solved.

Content of application

In view of the above-mentioned deficiencies of the prior art, it is a first object of the present application to provide a fully automatic continuous vacuum cooling device having the advantages of small floor space and fast cooling speed.

The first purpose of the application is realized by the following technical scheme: a full-automatic continuous vacuum cooling device comprises a box body and a cooling mechanism for reducing the temperature in the box body, wherein a feed port and a discharge port are respectively arranged at two ends of the box body, and the cooling mechanism is arranged on the box body;

still including being used for isolated box and external seal assembly and being used for continuously carrying and the conveying mechanism of output material for the box, conveying mechanism with seal assembly locates respectively on the box, seal assembly is located the feed inlet with discharge gate department.

Preferably, the cooling mechanism comprises a condenser and a refrigeration assembly in communication with the condenser.

Preferably, the sealing assembly comprises a box door arranged on the outer wall of the box body and a first driving piece for driving the box door to open or close.

Preferably, the box body is provided with a plurality of vacuum pumps communicated with the interior of the box body.

Preferably, a plurality of layers of vacuum bins are arranged in the box body, and the adjacent vacuum bins are mutually independent.

Preferably, the conveying mechanism comprises an output assembly and an input assembly, and the output assembly and the input assembly are symmetrically arranged along the axis of the central shaft of the box body.

Preferably, the output assembly comprises a supporting seat and a conveying track arranged on the supporting seat, the conveying track is connected to the supporting seat in a sliding mode along the arrangement direction of the plurality of vacuum bins, and the supporting seat is provided with a driving assembly for driving the conveying track to slide.

Preferably, the drive assembly comprises an elevator and a second drive member connected to the elevator.

In view of the above-mentioned deficiencies of the prior art, a second objective of the present application is to provide an operating method using a fully automatic continuous vacuum cooling apparatus, so as to achieve the purpose of automatic continuous and uninterrupted production and improving production efficiency.

The second purpose of the application is realized by the following technical scheme: an operation method of a full-automatic continuous vacuum cooling device comprises the following operation steps:

s1, inputting materials: the conveying mechanism carries the material to be cooled to approach along the direction of the box body, the material passes through the feeding hole and is carried into the box body, and then the conveying mechanism moves to the next station for carrying the material;

s2, sealing the box body: after the conveying mechanism conveys the materials into the box body, the feeding hole and the discharging hole are sealed by the sealing assembly, so that a closed box body space is provided for the box body;

s3, operating the box body cooling mechanism in the box body to cool the sealed space in the box body for 5 minutes after the operation;

s4, outputting materials: after the box body is subjected to cold cutting, the sealing assembly is opened, the cooled material is extruded out of the box body after being extruded, the material is conveyed to the conveying mechanism through the discharge port, and the cooled material is conveyed out through the conveying mechanism.

To sum up, the beneficial effect that this application has:

1. placing food to be cooled on a conveying mechanism, transferring the material to be cooled by the conveying mechanism, placing the material to be cooled into a box body through a feed port, then isolating the box body from the outside under the action of a sealing assembly, realizing independent placing and sealing of the material to be cooled, cooling and processing the sealed material by a cooling mechanism, presetting cooling time in the box body, after the cooling time is finished, forcibly pushing the cooled material out from a discharge port through the material to be cooled, carrying the pushed cooled material by the conveying mechanism, and then outputting the cooled material through the conveying mechanism, thereby realizing the purpose of automatic uninterrupted continuous production and improving the production efficiency;

2. under a certain state, along with the reduction of environmental pressure, the boiling point of water is also reduced, the heat consumed by the water for evaporating unit mass is increased, the vacuum cooling is realized by artificially realizing a low-pressure vacuum state, so that the moisture in the material of the vacuum cooling tank is quickly evaporated under the low-pressure state, the internal energy of the material is greatly reduced due to the absorption of self heat of a large amount of water molecules, namely, when the water molecules are quickly transferred, the heat in the material is also taken away rapidly, therefore, after the device seals the box body through the sealing component, the vacuum pump is used for pumping the air in the box body, so that the pressure in the box body is continuously reduced, and then shorten the cooling time of material greatly, and through the setting that utilizes a plurality of vacuum storehouse, and then improve space utilization to this realization reduces the mesh in occupation of land space.

Drawings

Fig. 1 is a schematic structural diagram of the whole of the first embodiment of the present application;

FIG. 2 is a partial cross-sectional view of an output assembly according to a first embodiment of the present application;

FIG. 3 is a schematic structural diagram of the whole of the second embodiment of the present application;

fig. 4 is a schematic structural diagram of a third embodiment of the present application in which a second embodiment of the present application is installed.

Reference numerals: 1. a box body; 11. an interlayer; 12. a vacuum bin; 2. a cooling mechanism; 21. a condenser; 22. a refrigeration assembly; 3. a seal assembly; 31. a box door; 32. a first driving member; 4. a conveying mechanism; 41. an input component; 42. an output component; 421. a supporting seat; 422. a conveying track; 423. a drive assembly; 4231. an elevator; 4232. a second driving member; 5. a wall body; 6. an external mechanism; 7. a translation frame; 8. a support; 81. a hoisting wheel; 82. and (4) hanging rails.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, refer to an orientation or positional relationship illustrated in the drawings for convenience in describing the present application and to simplify description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

The first embodiment is as follows: a full-automatic continuous vacuum cooling device is disclosed, referring to fig. 1 and fig. 2, and comprises a box body 1 and a cooling mechanism 2 for reducing the temperature in the box body 1, wherein a feed inlet and a discharge outlet are respectively arranged at two ends of the box body 1, and the cooling mechanism 2 is arranged on the box body 1;

still including being used for isolated box 1 with external seal assembly 3 and being used for box 1 to continue to carry and the conveying mechanism 4 of output material, conveying mechanism 4 with seal assembly 3 locates respectively on the box 1, seal assembly 3 is located the feed inlet with discharge gate department.

This embodiment will treat that cooling food places on conveying mechanism 4, will treat that refrigerated material moves by conveying mechanism 4 and carry, will treat that refrigerated material is placed into box 1 through the feed inlet, later in sealing component 3's effect, make box 1 isolated with external, realize treating independent placing and sealing of refrigerated material, sealed material is in the cooling process through cooling mechanism 2, through the cooling time in presetting box 1, treat after the cooling time, the material after the cooling process is released by the discharge gate through treating refrigerated material by force, the refrigerated material after the release is carried by conveying mechanism 4, later through the good material of conveying mechanism 4 output cooling.

Specifically, the cooling mechanism 2 includes a condenser 21 and a refrigeration assembly 22 in communication with the condenser 21.

This embodiment is through condenser 21 and refrigeration subassembly 22 to box 1 cooling process, and refrigeration subassembly 22 passes through the pipeline and communicates with box 1, sets up condenser 21 in the pipeline, and this condenser 21 is the cold trap, and the refrigeration subassembly 22 of this implementation is the compressor.

Specifically, the sealing assembly 3 includes a door 31 disposed on an outer wall of the box body 1 and a first driving member 32 for driving the door 31 to open or close.

This embodiment is connected with chamber door 31 through rotating on box 1, later utilizes first driving piece 32 to open chamber door 31, and the back is opened to chamber door 31, places the material into the incasement through conveying mechanism 4, recycles first driving piece 32 and closes chamber door 31 to this seals box 1, later carries out cooling treatment through cooling body 2 to box 1. The first drive member 32 in this embodiment is a cylinder. The box door 31 comprises a feeding box door 31 and a discharging box door 31, wherein the feeding box door 31 is positioned at the feeding opening, and the discharging box door 31 is positioned at the discharging opening.

Specifically, the box body 1 is provided with a plurality of vacuum pumps communicated with the interior of the box body 1.

The vacuum pump is arranged in the embodiment, the vacuum pump is connected with the pipeline, after the box door 31 is closed, the vacuum treatment is carried out in the box body 1 through the vacuum pump, and then the box body 1 is refrigerated through the cooling mechanism 2. In the present embodiment, roots, a water ring and a steam jet vacuum pump are used in combination to extract air from the chamber 1. In this embodiment, a vacuum monitoring instrument is further provided, and the vacuum monitoring instrument is a pressure tester and is used for vacuum monitoring of the vacuum degree in the box body 1 by testing the air pressure value in the box body 1.

Under certain state, along with the reduction of environmental pressure, the boiling point of water is also reducing, but the heat that its evaporation unit mass water consumed is increasing, vacuum cooling relies on artificially to realize the vacuum state of low atmospheric pressure, make the moisture content in the material of vacuum cooling tank evaporate rapidly under the state of low atmospheric pressure, the great migration of hydrone is because absorbed self heat, just make the great reduction of the internal energy of material, that is to say, the hydrone is when migrating rapidly, also taken away the inside heat of material rapidly, for this reason the device passes through seal assembly 3 with box 1 after sealed, utilize the vacuum pump to take out the air of box 1, make the inside pressure of box 1 continuously reduce, and then shorten the cooling time of material greatly.

Specifically, a plurality of layers of vacuum bins 12 are arranged in the box body 1, and the adjacent vacuum bins 12 are independent.

This embodiment is through setting up multilayer vacuum storehouse 12 on box 1, and mutual independence between the adjacent vacuum storehouse 12, through the setting of vacuum storehouse 12, improves box 1's space utilization. The single box 1 is arranged in this embodiment, five vacuum chambers 12 are arranged in the box 1, each vacuum chamber 12 is provided with a corresponding group of sealing box doors 31, and is driven by a first driving piece 32, so that the box doors 31 are opened and closed, the box doors 31 are arranged, the materials can be conveniently output and input, and the vacuum chambers 12 are independent and sealed through the box doors 31. And the arrangement of a plurality of vacuum bins 12 is utilized, so that the space utilization rate is improved, and the aim of reducing the occupied space is fulfilled.

The material to be cooled is moved by the conveying mechanism 4, the material to be cooled is placed into the vacuum chamber 12 through the feeding port, then the first driving part 32 drives the closed chamber door 31 to isolate the vacuum chamber 12 from the outside, so that the material to be cooled is placed and sealed separately, the sealed material is in the vacuum chamber 12, the vacuum pump in the vacuum chamber 12 starts to pump air, and the vacuum monitoring instrument is also monitoring the pressure value, wherein the vacuum monitoring instrument is a pressure tester, when the pressure value reaches a preset requirement, the refrigerating assembly 22 and the cold trap simultaneously cool the chamber body 1, after the cooling time is over, the preset cooling time in the embodiment is 5 minutes, of course, the 5 minutes is only a limited time, the longer the natural cooling time is better, the 5 vacuums of the cooled material are opened in sequence, according to the preset cooling time, through the discharging port, the continuous feeding and discharging are realized through the conveying mechanism 4.

In addition, when cooling down the material alone in the vacuum chamber 12, conveying mechanism 4 moves another material of waiting to cool off to another vacuum chamber 12, and this vacuum chamber 12 is to above-mentioned action of repeating, and this embodiment is provided with 5 vacuum chambers 12, and through cooperation cooling time and material conveying time, when accomplishing the cooling operation in first vacuum chamber 12, the material of waiting to cool off also just in time all to place in the remaining vacuum chamber 12 in the box 1. The conveying mechanism 4 returns to the vacuum bin 12 where the cooling operation is finished, the material to be cooled is pushed into the vacuum bin 12 where the cooling operation is finished, the cooled material is pushed out of the vacuum bin 12, the extruded material falls onto the conveying mechanism 4, and the conveying mechanism 4 carries the material to the external mechanism 6. And the conveying mechanism 4 moves to the next vacuum bin 12, so that the reciprocating operation is realized, and the purpose of full-motion continuous uninterrupted operation is realized.

Specifically, the conveying mechanism 4 comprises an output assembly 42 and an input assembly 41, and the output assembly 42 and the input assembly 41 are symmetrically arranged along the axis of the central shaft of the box body 1.

In the embodiment, by arranging the output assembly 42 and the input assembly 41, the input assembly 41 is used for conveying the material to be cooled into the box body 1, and the output assembly 42 is used for outputting the cooled material out of the box body 1. The conveying mechanism 4 is provided so as to be connected to an external mechanism 6, and the external mechanism 6 includes, for example, an external wrapping mechanism, a transfer mechanism, and the like.

Specifically, the output assembly 42 includes a support seat 421 and a conveying rail 422 disposed on the support seat 421, the conveying rail 422 is slidably connected to the support seat 421 along the arrangement direction of the plurality of vacuum chambers 12, and the support seat 421 is provided with a driving assembly 423 for driving the conveying rail 422 to slide.

Because a plurality of vacuum bins 12 are arranged in the box body 1, in order to conveniently realize automatic operation, the conveying track 422 is driven by the driving component 423 to slide along the supporting seat 421, so that materials are conveyed or output to each vacuum bin 12 through the conveying track 422.

Specifically, the driving assembly 423 includes a lift 4231 and a second driving member 4232 connected to the lift 4231.

The second driving member 4232 drives the elevator 4231 to move up and down, and the second elevator 4231 moves the conveying rail 422 up and down, and the second driving member 4232 is a servo motor.

In addition, an intermittent pushing member can be arranged in the box body 1, so that the material to be cooled can enter the box body conveniently and the cooled material can be output conveniently. The pusher can be a conveyor belt or a pneumatic cylinder.

Example two: a fully automatic continuous vacuum cooling device, referring to FIG. 3, the difference between this embodiment and the second embodiment is: the present embodiment is provided with a plurality of boxes 1, and a plurality of interlayers 11 for placing the material to be cooled are arranged between each box 1.

In this embodiment, the interlayer 11 is fully arranged by the pushing mechanism, the door 31 is closed by the first driving part 32, the pushing mechanism moves to the next box 1 through the moving frame, after the interlayer 11 in the box 1 fully arranges the material to be cooled, the door 31 is closed, the above actions are repeated, after the cooling time of the first box 1 is finished, the conveying mechanism 4 stops the tray arrangement operation, the box 1 is returned to the cooling time, the material to be cooled is placed into the box 1 again, the material to be cooled extrudes the material which is cooled out of the box 1, and the cooled material is transferred to the next working station through the conveying mechanism 4 for further processing. Continuous uninterrupted operation is realized through the sequential reciprocating circular operation.

The conveying mechanism 4 comprises an output assembly 42 and an input assembly 41, the output assembly 42 and the input assembly 41 are symmetrically arranged along the axis of the central shaft of the box body 1, and because the output assembly 42 and the input assembly 41 are to move back and forth between the box bodies 1, the translation frames 7 are respectively arranged on the two sides of the inlet and the outlet of the box body 1, and the translation frames 7 are arranged along the connecting line direction of the box bodies 1, so that the output assembly 42 and the input assembly 41 are respectively connected to the translation frames 7 in a sliding manner. The setting structure is simple and the operation is convenient.

The embodiment further comprises a support 8 arranged on the box body 1, a hanging rail 82 arranged on the support 8, and a plurality of hanging wheels 81 arranged on the feeding box door 31, wherein the hanging wheels 81 are slidably connected to the hanging rail 82.

The feeding box door 31 is pushed to make the feeding box door 31 slide on the hanging rail 82 through the hanging wheel 81, so as to realize the opening and closing of the feeding box door 31, and similarly, the feeding box door 31 is also identical to the feeding box door 31.

Example three: an operation method of a full-automatic continuous vacuum cooling device comprises the following operation steps:

s1, inputting materials: the conveying mechanism 4 carries the material to be cooled to approach along the direction of the box body 1, the material passes through the feeding hole and is carried into the box body 1, and then the conveying mechanism 4 moves to the next station for carrying the material;

the device realizes the purpose of the automatic feeding function of the conveying mechanism 4, and is convenient for subsequent operation.

S2, sealing the box body 1: after the conveying mechanism 4 conveys the materials into the box body 1, the feed inlet and the discharge outlet are sealed by the sealing component 3, so that a closed box body 1 space is provided for the box body 1;

in order to accelerate the cooling speed and improve the working efficiency, the device needs a closed space, the material to be cooled enters the box body 1, and the sealing component 3 seals the box body 1, so that the object to be cooled is completely sealed in the box body 1.

S3, cooling the box body 1: the cooling mechanism 2 works in the box body 1, so that the sealed space in the box body 1 is cooled for 5 minutes after the operation;

the cooling time can be adjusted adaptively according to the operation time, and the sealed box body 1 cools the material through the cooling mechanism 2, so that the purpose of automatic cooling processing is realized.

S4, outputting materials: after the box body 1 is subjected to cold cutting, the sealing assembly 3 is opened, the cooled material is extruded out of the box body 1 after being extruded, and is conveyed to the conveying mechanism 4 through the discharge port, and the cooled material is conveyed out through the conveying mechanism 4.

The sealing assembly 3 is opened, the cooled material is extruded out of the box body 1 after being extruded, and is conveyed to the conveying mechanism 4 through the discharge port, and the cooled material is accepted by the output assembly 42 of the conveying mechanism 4 and is transferred to the external mechanism 6. The purpose of automatic discharging is realized.

In this embodiment, the full-automatic continuous vacuum cooling device in the second embodiment is adopted, and the full-automatic continuous vacuum cooling device is installed on the wall 5, so as to achieve the purpose of automatic production, see fig. 4. The material to be cooled is placed into the input assembly 41 through the external mechanism 6, the input assembly 41 utilizes the cooperation of the lifter 4231 and the conveying track 422, the material to be cooled is placed into the interlayer 11 of the box body 1 one by one, after the interlayer 11 of the box body 1 is fully arranged, the input assembly 41 slides to another box body 1 through the translation frame, the interlayer 11 of the other box body 1 is fully arranged with the material to be cooled, the box body 1 fully arranged with the material is driven by the first driving piece 32 to drive the feeding box door 31 and the discharging box door 31 to slide along the hanging rail 82 on the bracket 8, the box door 31 slides on the hanging rail 82 through the hanging wheel 81 until the feeding box door 31 is attached to the feeding port, the first driving piece 32 stops working, after the feeding box door 31 and the discharging box door 31 are closed, the vacuum pump starts to evacuate air from the box body 1, when the pressure in the box body 1 reaches a certain pressure value, this pressure value is monitored through the vacuum monitor instrument, condenser 21 and refrigeration subassembly 22 in the cooling body 2 begin the collaborative work, through making the gaseous input of low temperature in to box 1, after cooling body 2 lasts the operation 5 minutes, ejection of compact chamber door 31 and feeding chamber door 31 open simultaneously, input subassembly 41 is through waiting to cool off the material and placing into intermediate layer 11 again, the material that has cooled off in the intermediate layer 11 is extruded intermediate layer 11, fall into on output assembly 42's delivery track 422, cooperation through delivery track 422 and lift 4231, carry the material that has cooled off to external mechanism 6 on, carry out cold chain processing on next step by external mechanism 6. The removal of material, accessible charging tray take up, should set up convenient and health.

The rest of this embodiment is the same as the first embodiment, and the unexplained features in this embodiment are explained by the first embodiment, which is not described herein again.

The above-mentioned embodiments are merely illustrative and not restrictive, and those skilled in the art can make modifications to the embodiments without inventive contribution as required after reading the present specification, but only protected by the patent laws within the scope of the claims of the present application.

Claims (9)

1. The utility model provides a full-automatic continuous type vacuum cooling device which characterized by: the cooling device comprises a box body (1) and a cooling mechanism (2) used for reducing the temperature in the box body (1), wherein a feeding hole and a discharging hole are respectively formed in two ends of the box body (1), and the cooling mechanism (2) is arranged on the box body (1);

still including being used for isolated box (1) and external seal assembly (3) and being used for box (1) to last conveying mechanism (4) of carrying and output material, conveying mechanism (4) with seal assembly (3) are located respectively on box (1), seal assembly (3) are located the feed inlet with discharge gate department.

2. The fully automatic continuous vacuum cooling device of claim 1, wherein: the cooling mechanism (2) comprises a condenser (21) and a refrigeration assembly (22) communicated with the condenser (21).

3. The fully automatic continuous vacuum cooling device of claim 2, wherein: the sealing assembly (3) comprises a box door (31) arranged on the outer wall of the box body (1) and a first driving piece (32) for driving the box door (31) to be opened or closed.

4. A fully automatic continuous vacuum cooling apparatus as claimed in claim 3, wherein: the box body (1) is provided with a plurality of vacuum pumps communicated with the interior of the box body (1).

5. The fully automatic continuous vacuum cooling device of claim 4, wherein: a plurality of layers of vacuum bins (12) are arranged in the box body (1), and the adjacent vacuum bins (12) are mutually independent.

6. The fully automatic continuous vacuum cooling device of claim 1, wherein: the conveying mechanism (4) comprises an output assembly (42) and an input assembly (41), and the output assembly (42) and the input assembly (41) are symmetrically arranged along the axis of the central shaft of the box body (1).

7. The fully automatic continuous vacuum cooling device of claim 6, wherein: the output assembly (42) comprises a supporting seat (421) and a conveying track (422) arranged on the supporting seat (421), the conveying track (422) is connected to the supporting seat (421) in a sliding mode along the arrangement direction of the vacuum bins (12), and a driving assembly (423) for driving the conveying track (422) to slide is arranged on the supporting seat (421).

8. The fully automatic continuous vacuum cooling device of claim 7, wherein: the drive assembly (423) comprises a lift (4231) and a second drive member (4232) connected to the lift (4231).

9. An operation method applying a full-automatic continuous vacuum cooling device is characterized by comprising the following steps: providing a fully automated continuous vacuum cooling apparatus as claimed in claim 1, the steps of operating comprising:

s1, inputting materials: the conveying mechanism (4) carries the material to be cooled to approach the box body (1) direction, penetrates through the feeding hole, carries the material into the box body (1), and then the conveying mechanism (4) moves to the next station for carrying the material;

s2, sealing the box body (1): after the conveying mechanism (4) conveys the materials into the box body (1), the feed inlet and the discharge outlet are sealed by the sealing component (3), and a closed box body (1) space is provided for the box body (1);

s3, operating the cooling mechanism (2) of the box body (1) in the box body (1) to cool the sealed space in the box body (1) for 5 minutes after the operation;

s4, outputting materials: after the box body (1) is subjected to cold cutting, the sealing assembly (3) is opened, the cooled material is extruded out of the box body (1) after being extruded, and is conveyed to the conveying mechanism (4) through the discharge port, and the cooled material is conveyed out through the conveying mechanism (4).

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