CN112830035A

CN112830035A - High-automation graphene electrothermal film production line

Info

Publication number: CN112830035A
Application number: CN202110092045.6A
Authority: CN
Inventors: 黄项州; 夏雨静; 黄诗淇; 夏宇皓
Original assignee: Zhongshan Junze Technology Co ltd
Current assignee: Hebei Bofeng New Energy Technology Co.,Ltd.
Priority date: 2021-01-23
Filing date: 2021-01-23
Publication date: 2021-05-25

Abstract

The invention relates to the technical field of graphene, in particular to a high-automation graphene electrothermal film production line which comprises a processing line, a detection line and a packing line which are sequentially arranged, wherein the processing line comprises an unreeling mechanism A, the left side of the unreeling mechanism A is sequentially provided with a corona device A, a traction device A and a slit coating head device, a drying mechanism A is arranged above the unreeling mechanism A, and a traction device B is arranged below the right side of the drying mechanism A, the high-efficiency automatic graphene electrothermal film production line completes automatic processing production of a graphene electrothermal film through the arranged processing line, the detection line and the packing line, full-automatic operation can greatly improve the production efficiency of enterprises and save labor, the automatic production line is modern in design, so that the production process is realized, the production energy consumption is greatly reduced, and the production industrial emission is reduced, the environmental pollution is reduced.

Description

High-automation graphene electrothermal film production line

Technical Field

The invention relates to the technical field of graphene, in particular to a high-automation production line for a graphene electrothermal film.

Background

Graphene is a two-dimensional periodic honeycomb lattice structure composed of carbon six-membered rings, and can be warped into zero-dimensional fullerene, rolled into one-dimensional carbon nanotubes or stacked into three-dimensional graphite, so that graphene is a basic unit for forming other graphite materials. The basic structural unit of the graphene is the most stable benzene six-membered ring in the organic material, and is the most ideal two-dimensional nanomaterial at present. The ideal graphene structure is a planar hexagonal lattice, which can be regarded as a layer of exfoliated graphite molecules, each carbon atom is hybridized by sp2, and contributes to electrons on the remaining p orbital to form a large pi bond, and pi electrons can move freely, so that the graphene is endowed with good conductivity. The two-dimensional graphene structure can be seen as the basic building block forming all sp2 hybrid carbonaceous materials. The graphene is a main raw material for preparing the far infrared electric heating film.

The existing graphene electrothermal film production equipment is low in intelligence, a large amount of labor is needed, and the production efficiency is low.

Disclosure of Invention

The invention aims to solve the defects of low production efficiency and the like in the prior art, and provides a high-automation graphene electrothermal film production line.

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

designing a high-automation graphene electrothermal film production line, which comprises a processing line, a detection line and a packing line which are sequentially arranged;

the processing line comprises an unwinding mechanism A, a corona device A, a traction device A and a slit coating head device are sequentially arranged on the left side of the unwinding mechanism A, a drying mechanism A is arranged above the unwinding mechanism A, a traction device B is arranged below the right side of the drying mechanism A, and a detection mechanism, a reticulate pattern gluing device, a drying mechanism B, a copper coil discharging device, a film spraying forming mechanism, a corona device B, an unwinding mechanism B, a welding trimming device, a traction device C and a sheet shearing mechanism are sequentially arranged on the right side of the traction device B.

Preferably, the detection mechanism comprises a resistance detection device, a flaw detection device A and a thickness measurement device which are sequentially arranged from left to right.

Preferably, a flaw detection device B is arranged at the top of the shearing machine.

Preferably, the drying mechanism A comprises a plurality of groups of drying ovens and a rack, and the plurality of groups of drying ovens are erected in the air in an arc structure through the rack.

Preferably, the detection line includes material loading conveying mechanism, the right side of material loading conveying mechanism is provided with the removal line, be provided with the manipulator between conveying mechanism and the removal line, resistance detection station, temperature detection station, artifical unwrapping wire station, press terminal station, soldering station and rubberizing tape station have from left to right set gradually on the removal line.

Preferably, a sucker is arranged at the top of the moving line, and the sucker reciprocates at the top of the moving line.

Preferably, the packing line comprises a jacket mechanism, the right side of the jacket mechanism is sequentially provided with a sheet storage area, a lamination mechanism, a box opening mechanism, a box sealing mechanism and a packing mechanism, a box loading manipulator is arranged between the lamination mechanism and the box opening mechanism, and the box loading manipulator is arranged between the box opening mechanism and the box sealing mechanism.

Preferably, a sampling inspection area is arranged between the lamination mechanism and the boxing manipulator.

Preferably, the right side of packing mechanism is provided with the pile up neatly machinery hand, the both sides of pile up neatly machinery hand are provided with the pallet stopper.

Preferably, stainless steel fences are arranged on the outer sides of the boxing manipulator and the stacking manipulator.

The invention provides a high-automation production line for a graphene electrothermal film, which has the beneficial effects that: according to the invention, automatic processing production of the graphene electrothermal film is completed through the arranged processing line, the detection line and the packing line, full-automatic operation can greatly improve the production efficiency of enterprises and save labor, and the production line is modern in design, so that production process automation is realized, the production energy consumption is greatly reduced, the production industrial discharge is reduced, the environmental pollution is reduced, and the method plays an important role in the development of the technical field.

Drawings

Fig. 1 is a schematic structural view of a processing line of a highly automated graphene electrothermal film production line according to the present invention;

FIG. 2 is a schematic diagram of a detection line structure of a highly automated graphene electrothermal film production line provided by the invention;

fig. 3 is a schematic structural diagram of a packing line of the highly automated graphene electrothermal film production line according to the present invention.

In the figure: 1. processing lines; 2. detecting lines; 3. packing wires; 4. an unwinding mechanism A; 5. a corona device A; 6. a traction device A; 7. a slit coating head device; 8. a drying mechanism A; 9. a traction device B; 10. a detection mechanism; 11. a reticulate pattern gluing device; 12. a drying mechanism B; 13. a copper coil unwinding device; 14. a laminating and forming mechanism; 15. a corona device B; 16. an unwinding mechanism B; 17. welding and trimming devices; 18. a traction device C; 19. a clip mechanism; 20. a conveying mechanism; 21. moving the wire; 22. a resistance detection station; 23. a temperature detection station; 24. a manual pay-off station; 25. pressing a terminal station; 26. a soldering station; 27. a taping station; 28. a suction cup machine; 29. an envelope mechanism; 30. a chip storage area; 31. a lamination mechanism; 32. a box opening mechanism; 33. a box sealing mechanism; 34. and (4) a packaging mechanism.

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.

Referring to fig. 1-3, a highly automated graphene electrothermal film production line comprises a processing line 1, a detection line 2 and a packing line 3 which are sequentially arranged;

the processing line 1 comprises an unreeling mechanism A4, a corona device A5, a traction device A6 and a slit coating head device 7 are sequentially arranged on the left side of an unreeling mechanism A4, a drying mechanism A8 is arranged above the unreeling mechanism A4, a traction device B9 is arranged below the right side of a drying mechanism A8, a detection mechanism 10, an anilox gluing device 11, a drying mechanism B12, a copper coil unreeling device 13, a film laminating forming mechanism 14, a corona device B15, an unreeling mechanism B16, a welding and trimming device 17, a traction device C18 and a sheet cutting mechanism 19 are sequentially arranged on the right side of the traction device B9, the detection mechanism 10 comprises a resistance value detection device, a defect detection device A and a thickness measuring device which are sequentially arranged from left to right, a defect detection device B is arranged at the top of the sheet cutting machine, the drying mechanism A8 comprises a plurality of baking ovens and a rack, and the ovens are arranged.

The coil film of the unreeling mechanism A4 is pulled out by a traction device A6, enters a slit coating head device 7 for coating by a corona device A5, an automatic feeding device is arranged on the slit coating head device 7 and is used for feeding the slit coating head device 7, the coil film after coating enters the drying mechanism A8 for drying, is pulled out by a traction device B9 and is sent into the detection mechanism 10 for corresponding detection, a copper coil is placed on two sides of the coil film by a copper coil discharging device 13 to form electrode plates and then is sent into the laminating and forming mechanism 14, the coil film on the unreeling mechanism B16 enters the laminating and forming mechanism 14 by a corona device B15, is compounded with the coil film of the unreeling mechanism A4 by the laminating and forming mechanism 14 and covers the outside of the electrode plates, and finally the compounded semi-finished product is pulled out by a traction device C18 and is welded and trimmed by a welding and trimming device 17 and a sheet cutting mechanism 19, thereby completing the entire process.

The detection line 2 comprises a feeding conveying mechanism 20, a moving line 21 is arranged on the right side of the feeding conveying mechanism 20, a manipulator is arranged between the conveying mechanism 20 and the moving line 21, a resistance detection station 22, a temperature detection station 23, a manual paying-off station 24, a terminal pressing station 25, a soldering station 26 and a tape adhering station 27 are sequentially arranged on the moving line 21 from left to right, a sucker 28 is arranged at the top of the moving line 21, and the sucker 28 reciprocates on the top of the moving line 21.

The semi-finished product is conveyed to the front end of the moving line 21 through the feeding conveying mechanism 20, the manipulator is used for taking materials and placing the materials on the moving line 21, multiple functions of the semi-finished product can be detected at each station, the sucker 28 feeds materials among the stations in a reciprocating mode, and efficiency is high.

The baling line 3 includes big envelope mechanism 29, big envelope mechanism 29's right side has set gradually and has deposited piece district 30, lamination mechanism 31, unpacking mechanism 32, joint sealing mechanism 33 and packing mechanism 34, be provided with the vanning manipulator between lamination mechanism 31 and the unpacking mechanism 32, the vanning manipulator sets up between unpacking mechanism 32 and joint sealing mechanism 33, be provided with the selective examination district between lamination mechanism 31 and the vanning manipulator, the right side of packing mechanism 34 is provided with the pile up neatly manipulator, the both sides of pile up neatly manipulator are provided with the pallet stopper, the outside of vanning manipulator and pile up neatly manipulator all is provided with the stainless steel rail.

The finished product encapsulates via big envelope mechanism 29, and unpacking mechanism 32 is used for opening the carton, and the carton removes to joint sealing mechanism 33 one side, and the finished product after the encapsulation is put to the inside of carton through the case packer manipulator, and the carton after putting full carries out joint sealing and packing through joint sealing mechanism 33 and packaging mechanism 34, puts the carton that packs well on the pallet in the pallet stop block in proper order through pile up neatly manipulator at last to accomplish the packing.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides a high automatic graphite alkene electric heat membrane production line which characterized in that: comprises a processing line (1), a detection line (2) and a packing line (3) which are arranged in sequence;

processing line (1) is including unwinding mechanism A (4), the left side of unwinding mechanism A (4) has set gradually corona unit A (5), draw gear A (6) and slit and has scribbled first device (7), the top of unwinding mechanism A (4) is provided with stoving mechanism A (8), the right side below of stoving mechanism A (8) is provided with draw gear B (9), the right side of draw gear B (9) has set gradually detection mechanism (10), reticulation rubber coating device (11), stoving mechanism B (12), has put copper and has rolled up device (13), drenched membrane forming mechanism (14), corona unit B (15), unwinding mechanism B (16), welding trimming device (17), draw gear C (18) and cut piece mechanism (19).

2. The high automation graphite alkene electric heat membrane production line of claim 1, its characterized in that: the detection mechanism (10) comprises a resistance value detection device, a flaw detection device A and a thickness measurement device which are sequentially arranged from left to right.

3. The high automation graphite alkene electric heat membrane production line of claim 2, its characterized in that: and a flaw detection device B is arranged at the top of the sheet shearing machine.

4. The high automation graphite alkene electric heat membrane production line of claim 3, its characterized in that: the drying mechanism A (8) comprises a plurality of groups of drying ovens and a rack, wherein the plurality of groups of drying ovens are erected in the air in an arc structure through the rack.

5. The high automation graphite alkene electric heat membrane production line of claim 1, its characterized in that: the detection line (2) comprises a feeding conveying mechanism (20), a moving line (21) is arranged on the right side of the feeding conveying mechanism (20), a mechanical hand is arranged between the conveying mechanism (20) and the moving line (21), and a resistance detection station (22), a temperature detection station (23), a manual paying-off station (24), a terminal pressing station (25), a tin soldering station (26) and an adhesive tape pasting station (27) are sequentially arranged on the moving line (21) from left to right.

6. The high automation graphite alkene electric heat membrane production line of claim 5, its characterized in that: the top of the moving line (21) is provided with a sucker (28), and the sucker (28) moves on the top of the moving line (21) in a reciprocating mode.

7. The high automation graphite alkene electric heat membrane production line of claim 1, its characterized in that: the packing wire (3) comprises a jacket mechanism (29), a film storage area (30), a laminating mechanism (31), a box opening mechanism (32), a box sealing mechanism (33) and a packing mechanism (34) are sequentially arranged on the right side of the jacket mechanism (29), a box loading mechanical arm is arranged between the laminating mechanism (31) and the box opening mechanism (32), and the box loading mechanical arm is arranged between the box opening mechanism (32) and the box sealing mechanism (33).

8. The high automation graphite alkene electric heat membrane production line of claim 7, its characterized in that: and a sampling inspection area is arranged between the lamination mechanism (31) and the boxing manipulator.

9. The high automation graphite alkene electric heat membrane production line of claim 8, its characterized in that: a stacking mechanical arm is arranged on the right side of the packing mechanism (34), and pallet limiting blocks are arranged on two sides of the stacking mechanical arm.

10. The high automation graphite alkene electric heat membrane production line of claim 9, its characterized in that: and stainless steel fences are arranged on the outer sides of the boxing manipulator and the stacking manipulator.