CN114889323B

CN114889323B - High-efficient thermoprint tectorial membrane device

Info

Publication number: CN114889323B
Application number: CN202210470247.4A
Authority: CN
Inventors: 汤炼; 胡方斌
Original assignee: Hubei Xinglong Packaging Material Co ltd
Current assignee: Hubei Xinglong Packaging Material Co ltd
Priority date: 2022-04-28
Filing date: 2022-04-28
Publication date: 2023-07-21
Anticipated expiration: 2042-04-28
Also published as: CN114889323A

Abstract

The invention discloses a high-efficiency thermoprinting laminating device in the technical field of label manufacturing, which comprises a feeding roller and a receiving roller, wherein the left side of the feeding roller is elastically provided with a lifting glue spreading roller, the left side of the lifting glue spreading roller is connected with a connecting plate in a sliding way, the right side of the receiving roller is fixedly provided with an electric telescopic rod, the output end of the electric telescopic rod is fixedly connected with the connecting plate, the bottom end of the connecting plate is provided with a scraping mechanism, the scraping mechanism is used for extruding a film to be tightly attached to a plate, excessive glue on the surface of the film is scraped between the film and the plate, the front end of the connecting plate is provided with a cutting mechanism, the cutting mechanism is used for cutting the film into a shape matched with the plate while the scraping mechanism scrapes the material, the bottom end of the cutting mechanism is provided with a receiving mechanism, and the receiving mechanism is used for recovering the glue scraped by the scraping mechanism and storing the plate after laminating, so that the problem of machine blockage and damage caused by excessive glue in a traditional laminating mode is solved.

Description

High-efficient thermoprint tectorial membrane device

Technical Field

The invention relates to the technical field of label manufacturing, in particular to a high-efficiency thermoprinting laminating device.

Background

The thermoprinting laminating machine is to press the thermoprinting foil onto the board, melt the adhesive layer of the thermoprinting foil to separate the pigment carrier from the paper base, hot press the image pigment onto the printed surface until the pigment adheres to the printed surface, and then cover a layer of transparent plastic film with thickness of 0.012-0.020 mm on the surface of the printed product to form a paper-plastic integrated product processing device.

In the prior art, a film with the surface coated with glue is required to be covered on the surface of a printed product subjected to hot stamping, then the film and the printed product pass through a compression roller together for lamination, when the film is extruded, redundant glue on the surface of the film can be extruded and piled at a feed inlet of the compression roller, the glue is piled for a long time to block subsequent feeding and compression operation, and meanwhile, the service life of a machine is reduced, so that workers need to clean residual glue in the machine frequently, and the glue is difficult to clean when a traditional hot stamping laminating device is used for laminating.

Based on the above, the invention designs a high-efficiency thermoprinting laminating device, which aims to solve the problems that in the prior art, a film with glue coated on the surface is required to be covered on the surface of a thermoprinted printing product, then the film and the printing product pass through a compacting roller together for lamination, when the film is extruded, excessive glue on the surface of the film can be extruded and accumulated at a feed port of the compacting roller, the glue is accumulated for a long time to prevent subsequent feeding and compacting operation, and meanwhile, the service life of a machine is reduced, so that staff is required to clean the residual glue in the machine frequently, and the glue is difficult to clean when the traditional thermoprinting laminating device is used for laminating.

Disclosure of Invention

The invention aims to provide a high-efficiency thermoprinting laminating device so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a high-efficient thermoprint tectorial membrane device, includes the feed roll, receives the material roller, the left side elasticity of feed roll is provided with the lift rubber coating roller, the left side slip of lift rubber coating roller is connected with the connecting plate, receive the right side fixed mounting of material roller has electric telescopic handle, electric telescopic handle's output is connected with the connecting plate stationary phase, the bottom of connecting plate is provided with scrapes material mechanism, scrape material mechanism and be used for extruding the film and make it closely laminate with the plate, and with the unnecessary glue in film surface from scraping between film and the plate, the front end of connecting plate is provided with cutting mechanism, cutting mechanism is used for cutting the film into the shape with the plate adaptation when scraping the material mechanism and scraping, the bottom of cutting mechanism is provided with receives material mechanism, receive material mechanism is used for retrieving the glue of scraping the material mechanism and accomodating the plate that the tectorial membrane is accomplished;

as a further scheme of the invention, the scraping mechanism comprises an extrusion groove and a connecting groove which are formed in the middle of a connecting plate, a first limiting block is slidably connected in the middle of the extrusion groove, a lifting rod is fixedly arranged at the rear end of the first limiting block, a scraping plate is fixedly arranged at the front side of the bottom end of the lifting rod, a connecting rod is fixedly arranged at the top end of the lifting rod, a second limiting block is slidably connected in the middle of the connecting groove, and a connecting block is fixedly arranged at the rear end of the second limiting block, and penetrates through the connecting block and is elastically connected with the connecting rod;

as a further scheme of the invention, a limiting rod is fixedly arranged on the left side of the rear end of the lifting glue spreader, a limiting ring is fixedly arranged on the lower side of the right end of the connecting plate, and the limiting rod penetrates through the limiting ring and is connected with the limiting ring in a sliding manner;

as a further scheme of the invention, the cutting mechanism comprises a mounting box fixedly mounted at the front end of the material receiving mechanism, an extrusion block is elastically connected to the rear side of the mounting box, the rear end of the extrusion block is wedge-shaped, a force storage plate is fixedly mounted at the front end of the connecting plate, a force storage rod is elastically connected to the middle part of the force storage plate, a cutting ring is fixedly mounted at the bottom end of the force storage rod, and a force storage block is fixedly mounted at the front end of the cutting ring;

as a further scheme of the invention, a connecting ring is fixedly arranged at the rear side of the right end of the cutting ring, a sliding rod is fixedly arranged at the right side of the bottom end of the connecting plate, and the sliding rod penetrates through the connecting ring and is connected with the connecting ring in a sliding manner;

as a further scheme of the invention, the material receiving mechanism comprises a material receiving box arranged at the bottom end of a cutting ring, four rotating rods are rotationally connected to the top end of the material receiving box, material receiving plates are fixedly arranged in the middle of the rotating rods, limit grooves are formed in the top ends of the material receiving plates, the four limit grooves are mutually spliced into a rectangle, bevel gears are fixedly arranged at the end parts of the rotating rods and meshed with each other, a driving mechanism is arranged at the right end of the material receiving box and used for driving the four material receiving plates to turn upwards to give way after the cutting ring is cut, baffles are fixedly arranged at the top ends of the material receiving plates at the front side and the rear side, a material box is fixedly arranged at the left end of the material receiving plates, and a push-pull plate is slidingly connected to the middle of the bottom end of the material receiving box;

as a further scheme of the invention, the driving mechanism comprises a supporting rod fixedly arranged at the right end of the material receiving box, a supporting plate is fixedly arranged at the top end of the supporting rod, a rotating shaft is rotatably connected to the top end of the supporting plate, a driving gear is fixedly arranged at the front end of the rotating shaft, the rear end of the rotating shaft is connected with the rotating rod through a driving belt, an L-shaped rod is elastically connected to the top end of the supporting plate, a driving rack is fixedly arranged at the right end of the L-shaped rod, the driving rack is meshed with the driving gear, a driving box is fixedly arranged at the right side of the front end of the cutting ring, a driving block is elastically connected to the right side of the driving box, and the right end of the driving block is wedge-shaped;

as a further scheme of the invention, a recovery box is fixedly arranged at the left end of the material receiving box, a discharge hole is formed in the front end of the recovery box, and a sealing plate is connected in the middle of the discharge hole in a sliding manner.

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

1. according to the invention, the scraping mechanism is arranged, the electric telescopic rod is started to drive the connecting plate to move downwards, the scraping plate is driven to slide at the top end of the plate in the process of moving downwards, the scraping plate slides to drive the film to be gradually attached to the left end from the right end of the plate, and the scraping plate extrudes gas between the plate and the film to the left, so that bubbles on the processed film are avoided, the defect rate of a product is reduced, and the quality of the product is improved; when the scraper blade scrapes left at the top of film, the scraper blade scrapes unnecessary glue on the film from the left end of plate, has solved in traditional tectorial membrane mode unnecessary glue pile up the problem that causes the machine to damage in the machine, has improved the life of machine, has avoided unnecessary glue to cause the interference to the tectorial membrane work of follow-up plate, has provided convenience for the use of machine for the staff need not frequent glue in the clearance machine, has significantly reduced staff's work load, has saved the labour, has improved the efficiency of production and processing.

2. According to the invention, the receiving mechanism is arranged, after the cutting mechanism finishes cutting, redundant films are adhered to the top end of the receiving plate, the cutting ring moves upwards to drive the receiving plate to rotate through the driving mechanism until the receiving plate rotates from a horizontal state to a vertical state, at the moment, the plates fall into the receiving box from among the four receiving plates, and the processed plates are stacked on the top end of the push-pull plate through cyclic reciprocating operation, so that the plates are greatly convenient for staff to arrange and package; when the material receiving plate is turned upwards, the film adhered to the top end of the material receiving plate is slowly torn off, so that the film adhesion on the material receiving plate is prevented from influencing the film covering operation of the next group of plates; when the scraping plate scrapes the film from right to left, redundant glue on the film overflows from two sides of the film, and at the moment, the glue is blocked by the baffle and moves leftwards under the scraping action of the scraping plate until the scraping plate scrapes the glue into the material box, so that the glue is prevented from overflowing from two sides of the film and dripping on a machine or the ground.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present invention;

FIG. 3 is a schematic view of a rear side view of the present invention;

FIG. 4 is a schematic view of the connection structure of the connecting plate and the cutting ring according to the present invention;

FIG. 5 is a schematic view showing the internal structure of the recycling bin of the present invention;

FIG. 6 is a schematic view of the connection structure of the rotating rod and the driving belt of the present invention;

FIG. 7 is a schematic diagram of the internal structure of the material receiving box.

In the drawings, the list of components represented by the various numbers is as follows:

1. a feed roller; 2. a receiving roller; 3. lifting the glue spreading roller; 4. a connecting plate; 5. an extrusion groove; 6. a connecting groove; 7. a first limiting block; 8. a lifting rod; 9. a scraper; 10. a connecting rod; 11. a second limiting block; 12. a connecting block; 13. a limit rod; 14. a baffle; 15. a limiting ring; 16. an electric telescopic rod; 17. a mounting box; 18. extruding a block; 19. a force storage plate; 20. a force storage rod; 21. cutting the ring; 22. a force storage block; 23. a connecting ring; 24. a slide bar; 25. a material receiving box; 26. a rotating lever; 27. a material collecting plate; 28. a limit groove; 29. a magazine; 30. bevel gears; 31. a recovery box; 32. a push-pull plate; 33. a support rod; 34. a support plate; 35. a rotating shaft; 36. a drive gear; 37. a transmission belt; 38. an L-shaped rod; 39. a drive rack; 40. a drive box; 41. a driving block; 42. a discharge port; 43. and (5) sealing the plate.

Description of the embodiments

Referring to fig. 1-7, the present invention provides a technical solution: the utility model provides a high-efficient thermoprint tectorial membrane device, including feed roll 1, receive material roller 2, the left side elasticity of feed roll 1 is provided with lift rubber coating roller 3, the left side slip of lift rubber coating roller 3 is connected with connecting plate 4, the right side fixed mounting of material roller 2 has electric telescopic handle 16, electric telescopic handle 16's output is connected with connecting plate 4 stationary phase, the bottom of connecting plate 4 is provided with scrapes material mechanism, scrape material mechanism and be used for pressing the film and make it closely laminate with the plate, and scrape unnecessary glue on film surface from between film and the plate, the front end of connecting plate 4 is provided with cutting mechanism, cutting mechanism is used for scraping the material mechanism and scraping the material and is cut the film into the shape that suits with the plate, the bottom of cutting mechanism is provided with material mechanism, material mechanism is used for retrieving the glue that scrapes material mechanism and accomodates the plate that the tectorial membrane is accomplished;

the scraping mechanism comprises an extrusion groove 5 and a connecting groove 6 which are formed in the middle of a connecting plate 4, a first limiting block 7 is slidably connected in the middle of the extrusion groove 5, a lifting rod 8 is fixedly arranged at the rear end of the first limiting block 7, a scraping plate 9 is fixedly arranged at the front side of the bottom end of the lifting rod 8, a connecting rod 10 is fixedly arranged at the top end of the lifting rod 8, a second limiting block 11 is slidably connected in the middle of the connecting groove 6, a connecting block 12 is fixedly arranged at the rear end of the second limiting block 11, and the connecting rod 10 penetrates through the connecting block 12 and is elastically connected with the connecting block 12;

when the device works, firstly, a film is wound according to the diagram shown in the figure 1, then, a plate after hot stamping is placed at the top end of a receiving mechanism, a feeding roller 1 and a receiving roller 2 are started, the feeding roller 1 and the receiving roller 2 rotate to drive the film to be conveyed to the left side, and the lower surface of the film is glued by a lifting gluing roller 3 in the moving process of the film until the film at the top end of the plate is glued; starting an electric telescopic rod 16, starting the electric telescopic rod 16 to drive a connecting plate 4 to move downwards, driving a lifting rod 8 and a scraping plate 9 to move downwards by the downwards movement of the connecting plate 4, driving a connecting block 12 to move leftwards by the leftwards movement of the lifting rod 8, driving a second limiting block 11 to slide in a connecting groove 6 by the leftwards movement of the connecting block 12, gradually approaching the first limiting block 7 and the second limiting block 11, gradually keeping the top end of the connecting block 10 away from the connecting block 12, and downwards pulling the connecting block 10 by elasticity to enable the connecting block 10 to push the scraping plate 9 downwards, so that the scraping plate 9 is always tightly attached to the top end of a plate while moving leftwards; the scraping plate 9 slides leftwards to drive the film to be attached to the left end gradually from the right end of the plate until the connecting plate 4 can not move downwards any more, at the moment, the top end of the plate is covered by the film, meanwhile, the cutting mechanism cuts the film downwards, the film is cut into a size matched with the plate, the plate after the hot stamping coating is completed is stored by the material receiving mechanism after the cutting mechanism cuts, the processed plate is stacked in the material receiving mechanism, and the plate is convenient for workers to arrange and package; when the scraping plate 9 is used for coating films from the right end to the left end of the plate, the scraping plate 9 extrudes gas between the plate and the film leftwards, so that bubbles on the processed film are avoided, the defect rate of the product is reduced, and the quality of the product is improved; when scraper blade 9 scrapes left at the top of film, scraper blade 9 scrapes unnecessary glue on the film out from the left end of plate, has solved in traditional tectorial membrane mode unnecessary glue pile up the problem that causes the machine to damage in the machine, has improved the life of machine, has avoided unnecessary glue to cause the interference to the tectorial membrane work of follow-up plate, has provided convenience for the use of machine for the staff need not frequent clearance glue in the machine, has significantly reduced staff's work load, has saved the labour, has improved the efficiency of production and processing.

As a further scheme of the invention, a limiting rod 13 is fixedly arranged on the left side of the rear end of the lifting glue spreader 3, a limiting ring 15 is fixedly arranged on the lower side of the right end of the connecting plate 4, and the limiting rod 13 passes through the limiting ring 15 and is connected with the limiting ring in a sliding manner; during operation, the connecting plate 4 moves downwards to drive the limiting ring 15 to slide on the outer side of the limiting rod 13, and at the moment, the limiting rod 13 limits the limiting ring 15, so that the stability of the connecting plate 4 during movement is improved, and the connecting plate 4 is prevented from shifting during movement.

As a further scheme of the invention, the cutting mechanism comprises a mounting box 17 fixedly mounted at the front end of the material collecting mechanism, an extrusion block 18 is elastically connected to the rear side of the mounting box 17, the rear end of the extrusion block 18 is wedge-shaped, a force storage plate 19 is fixedly mounted at the front end of the connecting plate 4, a force storage rod 20 is elastically connected to the middle part of the force storage plate 19, a cutting ring 21 is fixedly mounted at the bottom end of the force storage rod 20, and a force storage block 22 is fixedly mounted at the front end of the cutting ring 21;

during operation, the connecting plate 4 moves downwards and drives the force storage rod 20 to move downwards through the force storage plate 19, the force storage rod 20 moves downwards and drives the cutting ring 21 and the force storage block 22 to move downwards until the force storage block 22 is blocked by the extrusion block 18 and can not move downwards any more, at this time, the connecting plate 4 continues to move downwards, when the top end of a plate is completely covered by a film, the connecting plate 4 moves downwards and pushes the cutting ring 21 and the force storage block 22 to move downwards through the force storage plate 19, at this time, the extrusion block 18 is extruded by the force storage block 22 to move inwards of the mounting box 17 until the force storage block 22 passes over the extrusion block 18, the force storage rod 20 pushes the cutting ring 21 to move downwards under the action of elastic force, and the cutting ring 21 moves downwards to cut the film at the top end of the plate, so that the film is cut into a shape and a size matched with the plate, and the film are cut while the film and the plate are pressed by the scraper 9, the cutting efficiency is greatly improved, the processed product is more standard, and the cost of the processed by using an extra cutting machine is reduced.

As a further scheme of the invention, a connecting ring 23 is fixedly arranged at the rear side of the right end of the cutting ring 21, a slide bar 24 is fixedly arranged at the right side of the bottom end of the connecting plate 4, and the slide bar 24 passes through the connecting ring 23 and is connected with the connecting ring in a sliding way; during operation, the cutting ring 21 moves downwards to drive the connecting ring 23 to slide outside the slide rod 24, and at the moment, the slide rod 24 limits the connecting ring 23, so that the stability of the cutting ring 21 during movement is enhanced, and the cutting of the cutting ring 21 is more accurate.

As a further scheme of the invention, the material receiving mechanism comprises a material receiving box 25 arranged at the bottom end of a cutting ring 21, four rotating rods 26 are rotatably connected to the top end of the material receiving box 25, material receiving plates 27 are fixedly arranged in the middle of the rotating rods 26, limit grooves 28 are formed in the top ends of the material receiving plates 27, the four limit grooves 28 are mutually spliced into a rectangle, bevel gears 30 are fixedly arranged at the end parts of the rotating rods 26 and meshed with each other, a driving mechanism is arranged at the right end of the material receiving box 25 and used for driving the four material receiving plates 27 to turn upwards to give way after the cutting ring 21 is cut, baffles 14 are fixedly arranged at the top ends of the material receiving plates 27 at the front side and the rear side, a material box 29 is fixedly arranged at the left end of the material receiving plates 27, and a push-pull plate 32 is slidingly connected to the middle part of the bottom end of the material receiving box 25;

when the film cutting device works, the plate is placed in a rectangular frame formed by splicing the four limiting grooves 28, the limiting grooves 28 limit the plate, and the plate is prevented from being cut by the cutting mechanism when the film is cut; when the scraping plate 9 scrapes the film from the right side to the left, the redundant film on the top end of the plate is adhered to the top end of the collecting plate 27, when the cutting mechanism cuts the film, the cutting ring 21 cuts the top end of the collecting plate 27 downwards, so that the redundant film is separated from the adhered film, after the cutting is finished, the redundant film is adhered to the top end of the collecting plate 27, the cutting ring 21 moves upwards to drive the right rotating rod 26 to rotate through the driving mechanism, the right rotating rod 26 rotates to drive the right collecting plate 27 to overturn upwards, the right rotating rod 26 rotates to drive the four rotating rods 26 to synchronously rotate through the bevel gears 30, the four connecting rods 10 rotate to drive the four collecting plates 27 to synchronously overturn upwards, the processed plate is jacked up until the collecting plates 27 rotate to be in a vertical state from a horizontal state, the plate falls into the collecting box 25 until the top end of the push-pull plate 32, the push-pull plate is stacked on the top end of the plate 32 after the push-pull plate is circularly reciprocated, and when the plate 32 needs to be taken out, the plate 32 is pulled out, and the plate is conveniently packed by a large worker; when the material receiving plate 27 is turned upwards, the film adhered to the top end of the material receiving plate 27 is slowly torn off, so that the film adhesion on the material receiving plate 27 is prevented from affecting the film covering operation of the next group of plates; the film is torn off by rotating the material receiving plate 27, so that the film is prevented from being torn when the film on the material receiving plate 27 is removed; when the scraper 9 scrapes the film from right to left, the excessive glue on the film overflows from the two sides of the film, and at this time, the glue is blocked by the baffle 14 and moves leftwards under the scraping action of the scraper 9 until the scraper 9 scrapes the glue into the material box 29, so that the glue is prevented from overflowing from the two sides of the film and dripping onto a machine or the ground.

As a further scheme of the invention, the driving mechanism comprises a supporting rod 33 fixedly arranged at the right end of a material receiving box 25, a supporting plate 34 is fixedly arranged at the top end of the supporting rod 33, a rotating shaft 35 is rotatably connected to the top end of the supporting plate 34, a driving gear 36 is fixedly arranged at the front end of the rotating shaft 35, the rear end of the rotating shaft is connected with a rotating rod 26 through a driving belt 37, an L-shaped rod 38 is elastically connected to the top end of the supporting plate 34, a driving rack 39 is fixedly arranged at the right end of the L-shaped rod 38, the driving rack 39 is meshed with the driving gear 36, a driving box 40 is fixedly arranged at the right side of the front end of a cutting ring 21, a driving block 41 is elastically connected to the right side of the driving box 40, and the right end of the driving block 41 is wedge-shaped;

in operation, when the cutting ring 21 moves downwards, the cutting ring 21 moves to drive the driving box 40 and the driving block 41 to move downwards, the driving block 41 is blocked by the horizontal end of the L-shaped rod 38 to slide towards the inner side of the driving box 40 in the downward moving process until the driving block 41 passes over the horizontal end of the L-shaped rod 38, at the moment, the driving block 41 is restored to the initial position under the action of elastic force, when the cutting ring 21 moves upwards after finishing cutting, the cutting ring 21 moves upwards through the driving box 40 to drive the driving block 41 to move upwards, the driving block 41 moves upwards to push the L-shaped rod 38 to move upwards, the L-shaped rod 38 moves upwards through the driving rack 39 to drive the driving gear 36 to rotate, the driving gear 36 rotates to drive the rotating shaft 35 to rotate, the rotation of the rotating shaft 35 drives the rotating rod 26 to rotate through the transmission belt 37 until the L-shaped rod 38 cannot move upwards again, at this time, the horizontal end of the L-shaped rod 38 pushes the driving block 41 to enable the L-shaped rod 38 to give way, when the driving block 41 moves upwards beyond the horizontal end of the L-shaped rod 38, the L-shaped rod 38 moves downwards under the action of elastic force, the L-shaped rod 38 moves downwards to drive the rotating rod 26 to rotate in the opposite direction through the driving rack 39 and the driving gear 36, the rotating rod 26 rotates in the opposite direction to drive the material collecting plate 27 to rotate until the material collecting plate 27 returns to the initial position, and therefore preparation is made for the next group of plate covering films, and the rotating rod 26 and the material collecting plate 27 are driven to rotate while the cutting ring 21 moves upwards.

As a further scheme of the invention, a recovery box 31 is fixedly arranged at the left end of the material receiving box 25, a discharge hole 42 is formed at the front end of the recovery box 31, and a sealing plate 43 is connected in a sliding manner at the middle part of the discharge hole 42; during operation, the left receiving plate 27 rotates to drive the material box 29 to rotate around the rotating rod 26, the material box 29 rotates to enable glue collected in the material box 29 to be poured into the recycling box 31, so that glue in the material box 29 is poured when the material box 29 rotates each time, when the glue in the recycling box 31 needs to be cleaned, only the sealing plate 43 needs to be pushed upwards until the discharge hole 42 is in an open state, and the glue is discharged from the discharge hole 42.

Claims

1. The utility model provides a high-efficient thermoprint tectorial membrane device, includes feed roll (1), receipts material roller (2), its characterized in that: the automatic feeding device is characterized in that a lifting glue spreader (3) is elastically arranged on the left side of the feeding roller (1), a connecting plate (4) is connected to the left side of the lifting glue spreader (3) in a sliding manner, an electric telescopic rod (16) is fixedly arranged on the right side of the receiving roller (2), the output end of the electric telescopic rod (16) is fixedly connected with the connecting plate (4), a scraping mechanism is arranged at the bottom end of the connecting plate (4) and is used for extruding a film to tightly adhere to a plate after hot stamping, redundant glue on the surface of the film is scraped between the film and the plate, a cutting mechanism is arranged at the front end of the connecting plate (4), the cutting mechanism is used for cutting the film into a shape matched with the plate while scraping by the scraping mechanism, and a receiving mechanism is arranged at the bottom end of the cutting mechanism and is used for recycling the glue scraped by the scraping mechanism and storing the plate after film covering;

the scraping mechanism comprises an extrusion groove (5) and a connecting groove (6) which are formed in the middle of a connecting plate (4), a first limiting block (7) is slidably connected in the middle of the extrusion groove (5), a lifting rod (8) is fixedly arranged at the rear end of the first limiting block (7), a scraping plate (9) is fixedly arranged at the front side of the bottom end of the lifting rod (8), a connecting rod (10) is fixedly arranged at the top end of the lifting rod (8), a second limiting block (11) is slidably connected in the middle of the connecting groove (6), a connecting block (12) is fixedly arranged at the rear end of the second limiting block (11), and the connecting rod (10) penetrates through the connecting block (12) and is elastically connected with the connecting block.

The cutting mechanism comprises a mounting box (17) fixedly mounted at the front end of the collecting mechanism, an extrusion block (18) is elastically connected to the rear side of the mounting box (17), the rear end of the extrusion block (18) is wedge-shaped, a force storage plate (19) is fixedly mounted at the front end of the connecting plate (4), a force storage rod (20) is elastically connected to the middle part of the force storage plate (19), a cutting ring (21) is fixedly mounted at the bottom end of the force storage rod (20), a force storage block (22) is fixedly mounted at the front end of the cutting ring (21), the connecting plate (4) moves downwards to drive the force storage rod (20) to move downwards through the force storage plate (19), the force storage rod (20) moves downwards to drive the cutting ring (21) and the force storage block (22) to move downwards until the force storage block (22) is blocked by the extrusion block (18), the connecting plate (4) continues to move downwards, when a top end of a plate is completely covered by a film, the force storage plate (4) is pushed to move downwards through the extrusion block (22) to the extrusion block (22) and then moves downwards through the extrusion block (18), the force storage rod (20) pushes the cutting ring (21) to move downwards under the action of elastic force, and the cutting ring (21) moves downwards to cut a film at the top end of the plate.

2. The efficient thermoprinting laminating device according to claim 1, wherein: the left side of the rear end of the lifting glue spreader (3) is fixedly provided with a limiting rod (13), the lower side of the right end of the connecting plate (4) is fixedly provided with a limiting ring (15), and the limiting rod (13) penetrates through the limiting ring (15) and is connected with the limiting ring in a sliding manner.

3. The efficient thermoprinting laminating device according to claim 1, wherein: the right end rear side of cutting ring (21) fixed mounting has go-between (23), the bottom right side fixed mounting of connecting plate (4) has slide bar (24), slide bar (24) pass go-between (23) and be connected with it in a sliding way.

4. The efficient thermoprinting laminating device according to claim 1, wherein: the material collecting mechanism comprises a material collecting box (25) arranged at the bottom end of a cutting ring (21), four rotating rods (26) are rotatably connected to the top end of the material collecting box (25), material collecting plates (27) are fixedly arranged in the middle of each rotating rod (26), limit grooves (28) are formed in the top ends of the material collecting plates (27), the limit grooves (28) are spliced into a rectangle, bevel gears (30) are fixedly arranged at the end parts of the rotating rods (26) and meshed with each other, a driving mechanism is arranged at the right end of the material collecting box (25) and used for driving the four material collecting plates (27) to turn upwards to yield plates after the cutting ring (21) cuts, baffles (14) are fixedly arranged at the top ends of the material collecting plates (27) on the front side and the rear side, material boxes (29) are fixedly arranged at the left ends of the material collecting plates (27), and push-pull plates (32) are slidably connected to the middle parts of the bottom ends of the material collecting box (25).

5. The efficient thermoprinting laminating device according to claim 4, wherein: the driving mechanism comprises a supporting rod (33) fixedly mounted at the right end of a receiving box (25), a supporting plate (34) is fixedly mounted at the top end of the supporting rod (33), a rotating shaft (35) is rotatably connected to the top end of the supporting plate (34), a driving gear (36) is fixedly mounted at the front end of the rotating shaft (35) and the rear end of the rotating shaft is connected with a rotating rod (26) through a transmission belt (37), an L-shaped rod (38) is elastically connected to the top end of the supporting plate (34), a driving rack (39) is fixedly mounted at the right end of the L-shaped rod (38), the driving rack (39) is meshed with the driving gear (36), a driving box (40) is fixedly mounted at the right side of the front end of the cutting ring (21), a driving block (41) is elastically connected to the right side of the driving box (40), and the right end of the driving block (41) is wedge-shaped.

6. The efficient thermoprinting laminating device according to claim 4, wherein: the left end of the material receiving box (25) is fixedly provided with a material recovering box (31), the front end of the material recovering box (31) is provided with a material outlet (42), and the middle part of the material outlet (42) is slidably connected with a sealing plate (43).