CN115157659A - Paper packaging box manufacturing and forming method based on 3D printing - Google Patents

Abstract

The invention discloses a paper packaging box manufacturing and forming method based on 3D printing, which comprises the steps of crushing fiber raw materials such as waste paper, waste paper boards and waste paper boxes, dissociating the crushed fiber raw materials into paper pulp by adopting a mechanical method, a chemical method or a method combining the mechanical method and the chemical method to prepare a coloring agent, wherein the coloring agent is used for dyeing a packaging paper box, designing the appearance shape of the packaging paper box by utilizing three-dimensional software, and then filling the prepared paper pulp and the coloring agent into a raw material box of a 3D printer respectively. According to the invention, through the matching of the structures, the packaging box can be simply and quickly printed and colored, the vegetable dye is arranged, the environment is protected, the formaldehyde is not released, the method for extracting the vegetable pigment is simple and practical, and the high-pressure spray head can be used for cleaning the interior of the spray head simply and quickly after being used for a period of time without being disassembled, so that the spray head is prevented from being blocked, and the spraying efficiency of the spray head is improved.

Description

Paper packaging box manufacturing and forming method based on 3D printing

Technical Field

The invention relates to the technical field of 3D printing of packaging boxes, in particular to a paper packaging box manufacturing and forming method based on 3D printing.

Background

The paper packaging box is manufactured and printed through the following processes of die cutting after printing the manufactured paper, then the paper is folded into the paper box, the paper is subjected to pulping and papermaking processes in the formation process, the pulping and papermaking processes are needed, related printing equipment is needed in the printing process, finally the paper box is needed to be dyed and fed after the paper is folded into the paper box, the operation process is complicated, a large amount of manpower and material resources are wasted, and meanwhile, the colored pigment easily releases harmful substances such as formaldehyde and the like, so that damage is easily caused to dyers and users.

Therefore, a paper packaging box manufacturing and forming method based on 3D printing is proposed.

Disclosure of Invention

The invention aims to provide a paper packaging box manufacturing and forming method based on 3D printing, which can simply and quickly print and color a packaging box, is environment-friendly and healthy due to the arrangement of plant dye, does not release formaldehyde, is simple and practical in a method for extracting plant pigment, can simply and quickly clean the interior of a spray head after the high-pressure spray head is used for a period of time without being disassembled, prevents the spray head from being blocked, improves the spraying efficiency of the spray head, and solves the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: the paper packaging box manufacturing and forming method based on 3D printing comprises the following steps:

s1: crushing fiber raw materials such as waste paper, waste paperboard, waste paper boxes and the like;

s2: dissociating the pulverized fiber raw material into paper pulp by adopting a mechanical method, a chemical method or a combination method of the mechanical method and the chemical method;

s3: preparing a coloring agent for dyeing the packaging carton;

s4: designing the appearance shape of the packaging paper box by using three-dimensional software;

s5: then filling the prepared paper pulp and the prepared coloring agent into a raw material box of a 3D printer respectively;

s6: starting a 3D printer, printing and forming the 3D printer according to the shape of the packaging paper box designed in the S4 through a high-pressure nozzle, and dyeing the packaging paper box after printing and forming by spraying a dyeing agent through the other high-pressure nozzle;

s7: and carrying out air drying treatment on the printed and molded packaging paper boxes, sequentially putting the packaging paper boxes on a rotary bottom plate of an air dryer, rotating the rotary bottom plate, and respectively blowing hot air to the upper parts and the side walls of the packaging paper boxes by dispersing hot air through an air outlet cover.

Preferably, the coloring agent in the S3 is a plant dye, is harmless to human bodies and is environment-friendly.

Preferably, the extraction method of the plant pigment comprises the following steps:

s1; taking a dye plant;

s2: cutting dye plants, boiling in water, and performing condensation and reflux;

s3: standing the solution, cooling, filtering with a sieve, and storing the leachate as plant pigment.

Preferably, the dye plants are leaves, vegetable leaves, fruit peels or petals of different colors, and are selected according to dyeing requirements.

Preferably, the screen is a 100 mesh screen.

Preferably, high pressure nozzle includes the flange discharging pipe of fixed mounting on the 3D printer, a plurality of screw thread post of bottom fixedly connected with of flange discharging pipe, the cover is equipped with the flange expansion hose that sends out with flange discharging pipe butt on the screw thread post, still the cover is equipped with the shower nozzle with flange expansion hose butt on the screw thread post, be equipped with on the screw thread post and be used for carrying out the elastic positioning subassembly fixed to flange expansion hose and shower nozzle.

Preferably, the elastic positioning assembly comprises a spring sleeved on a threaded column, and the threaded column is connected with a threaded sleeve used for pushing the spray head to abut against the flange telescopic hose and the flange telescopic hose to abut against the flange discharge pipe in a threaded manner.

Preferably, a scraping cylinder for dredging and cleaning the interior of the spray head is fixedly connected in the flange discharge pipe.

Compared with the prior art, the invention has the following beneficial effects:

1. through the setting of 3D printer for can go on in step with papermaking and packing carton, and can also color the packing carton after printing, reduce the waste of paper, shorten production flow, and through the setting of plant dyestuff, the environmental protection is healthy, can not release formaldehyde, draws plant pigment's method simple and practical.

2. Through the flange discharging pipe, flange expansion hose, the screw thread post, the shower nozzle, the swivel nut, the spring with scrape the setting of a section of thick bamboo, make after the shower nozzle is using a period, when need clear up its inside, under the condition of not dismantling the shower nozzle, the elasticity of overcoming the spring upwards promotes the shower nozzle and shifts up, the in-process that the shower nozzle was shifting up, scrape a section of thick bamboo and can inject in the shower nozzle, clear up the inner wall of shower nozzle, prevent that the shower nozzle from blockking up, the material spraying efficiency of shower nozzle has been improved, and under the effect of a plurality of spring elasticity, can promote flange expansion hose's both ends respectively with flange discharging pipe and the inseparable butt of shower nozzle.

3. Drying process is carried out for the packing carton on the rotating bottom plate through the heating pipe that sets up, and the heating pipe is the annular form, with peripheral gas heating back, blow through going out the gas hood and blow the heat and carry out even air-dry drying to the packing carton, guarantee the dry homogeneity of 3D spraying to gas after blowing filters under the effect of filter screen, is filtered in by the aspiration pump suction to going out the gas hood again after the filtration, thereby has reached thermal cyclic utilization, reduces the heat and scatters and disappears.

Drawings

FIG. 1 is a flow chart of the present invention;

FIG. 2 is a schematic view of a high pressure showerhead according to the present invention;

FIG. 3 is an exploded view of the present invention shown in FIG. 2;

fig. 4 is a schematic structural view of the air dryer of the present invention.

In the figure: 1. a flange discharge pipe; 2. a threaded post; 3. a flange flexible hose; 4. a spray head; 5. a spring; 6. a threaded sleeve; 7. a scraping cylinder; 11. a base; 12. an air drying chamber; 13. a rotating base plate; 14. a rotating shaft; 15. a bearing; 16. a driven gear; 17. a motor; 18. placing a door; 19. heating a tube; 110. an air outlet cover; 111. an air supply duct; 112. an air pump; 113. a first baffle plate; 114. a filter screen; 115. a second baffle.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. 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.

Referring to fig. 1 to 4, the present invention provides a technical solution: the paper packaging box manufacturing and forming method based on 3D printing comprises the following steps:

s1: crushing fiber raw materials such as waste paper, waste paper boards and waste paper boxes;

s2: dissociating the pulverized fiber raw material into paper pulp by adopting a mechanical method, a chemical method or a combination method of the mechanical method and the chemical method;

s3: preparing a dyeing agent for dyeing the packaging carton;

s4: designing the appearance shape of the packaging paper box by using three-dimensional software;

s5: then, filling the prepared paper pulp and the prepared coloring agent into a raw material box of a 3D printer respectively;

s6: starting a 3D printer, printing and forming the 3D printer according to the shape of the packaging paper box designed in the S4 through a high-pressure nozzle, and dyeing the packaging paper box after printing and forming by spraying a dyeing agent through the other high-pressure nozzle;

s7: the printed and formed packaging paper boxes are air-dried, and are sequentially placed on a rotary bottom plate 13 of an air dryer, the rotary bottom plate 13 rotates, and the air outlet covers 110 respectively blow hot air to the upper parts and the side walls of the packaging paper boxes in a dispersing manner.

The coloring agent in the S3 is a vegetable dye, is harmless to human bodies and is environment-friendly.

The extraction method of the plant pigment comprises the following steps:

s1; taking a dye plant;

s2: cutting dye plants, boiling in water, and performing condensation and reflux;

s3: standing the solution, cooling, filtering with a sieve, and storing the leachate as the plant pigment.

The pigment in plant body is extracted by water phase, the plant cell is boiled first, the cell wall is broken, and then the pigment in cell liquid flows out to the outside water solution as much as possible due to diffusion. The heating and boiling time is determined according to the plant amount and the amount of water, and finally, plant residues are filtered out through a sieve, so that the pigment is completely reserved in the filtrate to wait for being made into the coating.

The dye plants are leaves, vegetable leaves, fruit peels or petals with different colors, and are selected according to dyeing requirements, the dye plant raw materials are easy to obtain, and the manufacturing cost is low.

The sieve is a 100-mesh sieve, plant residues with larger particles are easily left in the solution due to the fact that the sieve is too large in holes, and the plant residues are easily blocked due to the fact that the sieve is too small in holes, so that the filtering efficiency is affected.

High pressure nozzle includes flange discharging pipe 1 of fixed mounting on the 3D printer, and a plurality of screw thread post 2 of bottom fixedly connected with of flange discharging pipe 1 is equipped with the flange bellows 3 that sends out with 1 butt of flange discharging pipe on the screw thread post 2, still overlaps on the screw thread post 2 to be equipped with the shower nozzle 4 with 3 butts of flange bellows, is equipped with on the screw thread post 2 to be used for carrying out the elastic locating component fixed to flange bellows 3 and shower nozzle 4.

The elastic positioning assembly comprises a spring 5 which is sleeved on a threaded column 2, and the threaded column 2 is connected with a threaded sleeve 6 which is used for pushing a spray head 4 to abut against a flange telescopic hose 3 and the flange telescopic hose to abut against a flange discharge pipe 1 in a threaded manner.

After shower nozzle 4 used a period, when needing to clear up its inside, under the condition of not dismantling shower nozzle 4, overcome spring 5's elasticity and upwards promote shower nozzle 4 and move up, shower nozzle 4 is at the in-process that shifts up, scrape a section of thick bamboo 7 and can inject in shower nozzle 4, clear up the inner wall of shower nozzle 4, prevent that shower nozzle 4 from blockking up, the material efficiency of spouting of shower nozzle 4 has been improved, and under the effect of 5 elasticity of a plurality of spring, can promote flange bellows 3's both ends respectively with flange discharging pipe 1 and the inseparable butt of shower nozzle 4.

Fixedly connected with scrapes a section of thick bamboo 7 that is used for 4 inside mediation clearance of shower nozzles in the flange discharging pipe 1.

In this embodiment, the air dryer includes a base 11, an air drying chamber 12 is disposed at the top end of the base 1, a rotating bottom plate 13 is disposed at the lower portion in the air drying chamber 12, a rotating shaft 14 is disposed at the bottom end of the rotating bottom plate 13, the rotating shaft 14 penetrates through the base 11 and extends into the base 11, a bearing 15 connected with the rotating shaft 14 is disposed on the bottom wall in the base 11, a driven gear 16 is nested on the outer wall of the rotating shaft 14 in the base 11, a driving gear is meshed with one side of the driven gear 16 and is coaxially connected with a rotating head of a motor 17, the motor 17 is disposed on the top wall of one side in the base 11, a plurality of packaging cartons can be placed on the upper portion of the rotating bottom plate 13, and the air drying operation of the packaging cartons in different directions is realized by using the rotating torque, so as to improve the drying efficiency;

the heating principle is as follows: the bottom wall of the other side in the base 11 is provided with an air pump 112, the base 1 on one side of the air pump 112 is provided with a first baffle 113, one side of the first baffle 113 is provided with a filter screen 114, one side of the filter screen 114 is provided with a second baffle 115, the output end of the air pump 112 is provided with an air supply pipeline 111, the tail end of the air supply pipeline 111 sequentially penetrates through the top wall of the base 11, the top wall of the air drying chamber 12 and is communicated with an air outlet cover 110 arranged in the middle of the top end in the air drying chamber 12, the outer side of the air outlet cover 110 is provided with a heating pipe 19 in a ring shape, the heating pipe 19 is in a ring shape and mainly disperses heat uniformly, so that when air is blown, heat can be uniformly blown into the side wall and the top surface of a packaging carton (the wind direction is shown by dotted lines in figure 4), after peripheral air is heated, the heat is blown to the packaging carton by the air outlet cover 110 to be uniformly air-dried, the uniformity of 3D spraying drying is ensured, and the blown air is filtered under the action of the filter screen 114, and then is pumped into the air-exhausted by the air-pumping pump 112 into the air-guiding pipeline 111, thereby reducing heat recycling and reducing heat.

In the embodiment, a placing door 18 is arranged on one side of the air drying chamber 12, and the placing door 18 is hinged with the air drying chamber 12, so that the packaging carton can be taken out conveniently, and meanwhile, the closed environment ensures that most of heat can be absorbed by the packaging carton;

in this embodiment, driven gear 16 outer wall, first baffle 113's lower part all is equipped with a plurality of through-holes, because filter screen 114 sets up to the stratiform, gaseous one side from the filter screen gets into, until circulating to the bottommost layer, flow into to air extracting pump 112 in from the through-hole at last, first baffle 113 and second baffle 115 are for the convenience of increasing filter screen 114's steadiness, the entering end of filter screen gets into on the lateral wall (side about non), then flow into inside bottommost layer, just connect the through-hole innermost layer, guarantee like this that the gas that flows out is filtered gas.

In this embodiment, the whole operation process of the air dryer can be controlled by a computer, and the automatic operation control is realized by adding a PLC and the like, and the signal feedback can be performed by setting a sensor, so as to realize the sequential implementation of the steps, which are conventional knowledge of the existing automatic control, and are not repeated in this embodiment.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. Paper packing carton manufacturing and forming method based on 3D prints, its characterized in that: the method comprises the following steps:

s1: crushing fiber raw materials such as waste paper, waste paper boards and waste paper boxes;

s2: dissociating the pulverized fiber raw material into paper pulp by adopting a mechanical method, a chemical method or a combination method of the mechanical method and the chemical method;

s3: preparing a dyeing agent for dyeing the packaging carton;

s4: designing the appearance shape of the packaging paper box by using three-dimensional software;

s5: then filling the prepared paper pulp and the prepared coloring agent into a raw material box of a 3D printer respectively;

s6: starting a 3D printer, printing and forming the 3D printer according to the shape of the packaging paper box designed in the S4 through a high-pressure spray head, and spraying a coloring agent from the other high-pressure spray head to dye the printed and formed packaging paper box;

s7: and carrying out air drying treatment on the printed and molded packaging paper boxes, sequentially putting the packaging paper boxes on a rotary bottom plate of an air dryer, rotating the rotary bottom plate, and respectively blowing hot air to the upper parts and the side walls of the packaging paper boxes by dispersing hot air through an air outlet cover.

2. The manufacturing and forming method of the paper packaging box based on 3D printing as claimed in claim 1, wherein: the coloring agent in the S3 is a plant dye, is harmless to human bodies and is environment-friendly.

3. The manufacturing and forming method of the paper packaging box based on 3D printing as claimed in claim 2, wherein: the extraction method of the plant pigment comprises the following steps:

s1; taking a dye plant;

s2: cutting dye plants, boiling in water, and performing condensation and reflux;

s3: standing the solution, cooling, filtering with a sieve, and storing the leachate as the plant pigment.

4. The paper packaging box manufacturing and forming method based on 3D printing as claimed in claim 3, characterized in that: the dye plants are leaves, vegetable leaves, fruit peels or petals with different colors and are selected according to dyeing requirements.

5. The manufacturing and forming method of the paper packaging box based on 3D printing as claimed in claim 3, wherein the manufacturing and forming method comprises the following steps: the sieve is a 100-mesh sieve.

6. The manufacturing and forming method of the paper packaging box based on 3D printing as claimed in claim 1, wherein: high pressure nozzle includes the flange discharging pipe of fixed mounting on the 3D printer, the bottom fixedly connected with a plurality of screw thread post of flange discharging pipe, the cover is equipped with the flange expansion hose that sends out with flange discharging pipe butt on the screw thread post, still the cover is equipped with the shower nozzle with flange expansion hose butt on the screw thread post, be equipped with on the screw thread post and be used for carrying out the elastic positioning subassembly fixed to flange expansion hose and shower nozzle.

7. The manufacturing and forming method of the paper packaging box based on 3D printing as claimed in claim 6, wherein the manufacturing and forming method comprises the following steps: the elastic positioning assembly comprises a spring sleeved on a threaded column, and the threaded column is connected with a threaded sleeve used for pushing the spray head to abut against the flange telescopic hose and the flange telescopic hose to abut against the flange discharge pipe in a threaded manner.

8. The paper packaging box manufacturing and forming method based on 3D printing as claimed in claim 6, characterized in that: and a scraping cylinder for dredging and cleaning the interior of the spray head is fixedly connected in the flange discharge pipe.

9. The manufacturing and forming method of the paper packaging box based on 3D printing according to any one of claims 1-4, characterized in that: the air dryer comprises a base, the base top is equipped with the air-drying chamber, the lower part in the air-drying chamber is equipped with rotating bottom plate, the rotating bottom plate bottom is equipped with the pivot, the pivot runs through the base and extends to in the base, be equipped with the bearing that is connected with the pivot on the diapire in the base, nested on the pivot outer wall in the base has driven gear, driven gear one side meshing is connected with the driving gear, the driving gear turns round coaxial coupling with the motor, the motor is established on one side roof in the base.

10. The paper packaging box manufacturing and forming method based on 3D printing as claimed in claim 9, characterized in that: the air-drying device is characterized in that an air pump is arranged on the bottom wall of the other side in the base, a first baffle is arranged on the base on one side of the air pump, a filter screen is arranged on one side of the first baffle, a second baffle is arranged on one side of the filter screen, an air supply pipeline is arranged at the output end of the air pump, the tail end of the air supply pipeline sequentially penetrates through the top wall of the base and the top wall of the air-drying chamber and is communicated with an air outlet cover arranged in the middle of the top end in the air-drying chamber, and a heating pipe is arranged on the outer side of the air outlet cover.

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