CN221091415U - Automatic laminating equipment of glass - Google Patents

Abstract

The utility model relates to the technical field of automatic glass film coating, in particular to automatic glass film coating equipment, which can not only carry out double-sided film coating on materials, but also carry out electric precipitation on the materials in the glass film coating process by arranging a film coating mechanism and a de-electric precipitation mechanism, thereby improving the processing efficiency; comprises a transportation mechanism; the device also comprises a film covering mechanism, a heating mechanism, a motor removing mechanism, a drying mechanism and a cutting mechanism, wherein the film covering mechanism is arranged on the conveying mechanism, the heating mechanism is arranged at the front end of the conveying mechanism, the motor removing mechanism is arranged at the lower end of the conveying mechanism, the drying mechanism is arranged on the conveying mechanism, and the cutting mechanism is arranged on the conveying mechanism; the conveying mechanism conveys, the film coating mechanism carries out film coating, the heating mechanism carries out heating, the static electricity removing mechanism carries out static electricity removing, the drying mechanism carries out drying, and the cutting mechanism carries out cutting.

Description

Automatic laminating equipment of glass

Technical Field

The utility model relates to the technical field of automatic glass film coating, in particular to automatic glass film coating equipment.

Background

After the glass is produced, processed and molded, a layer of protective film is required to be coated on the upper surface and the lower surface of the glass so as to prevent the surface of the glass from being scratched in the processes of transportation, packaging, installation and the like.

In the existing automatic glass film coating equipment, for example, the automatic glass film coating equipment disclosed in the patent application number 202020597625.1 is used for realizing the up-and-down movement of an upper film coating roller, and the distance between the upper film coating roller and a lower film coating roller is adjusted, so that the upper film coating roller and the lower film coating roller can meet the requirements of coating glass with different thicknesses.

However, in the process of coating glass, static electricity generated on the glass easily adsorbs dust, thereby resulting in coating quality.

Disclosure of utility model

In order to solve the technical problems, the utility model provides the automatic glass film coating equipment which is provided with the film coating mechanism and the electric removing mechanism, so that in the glass film coating process, not only can double-sided film coating be carried out on materials, but also electric removing and dust removing can be carried out on the materials, and the processing efficiency is improved.

The utility model relates to automatic glass laminating equipment, which comprises a conveying mechanism; the device also comprises a film covering mechanism, a heating mechanism, a motor removing mechanism, a drying mechanism and a cutting mechanism, wherein the film covering mechanism is arranged on the conveying mechanism, the heating mechanism is arranged at the front end of the conveying mechanism, the motor removing mechanism is arranged at the lower end of the conveying mechanism, the drying mechanism is arranged on the conveying mechanism, and the cutting mechanism is arranged on the conveying mechanism;

The conveying mechanism conveys, the film coating mechanism coats films, the heating mechanism heats, the static electricity removing mechanism removes static electricity, the drying mechanism dries, and the cutting mechanism cuts; through opening transport mechanism and transporting the material, remove the electric mechanism through opening and remove the work of destaticizing to the material, make drying mechanism dry the material through heating mechanism simultaneously, carry out the tectorial membrane through opening tectorial membrane mechanism to the material, heat the tectorial membrane through opening heating mechanism simultaneously, cut the material after the processing is accomplished through opening cutting mechanism to make glass tectorial membrane in-process, not only can carry out two-sided tectorial membrane to the material, can also remove the electric dust to the material, improve machining efficiency.

Preferably, the conveying mechanism comprises a bracket, a plurality of groups of conveying rollers, a plurality of groups of chain wheels, a chain and a motor I, wherein the plurality of groups of conveying rollers are rotatably arranged on the bracket, the output ends of the plurality of groups of conveying rollers extend to the rear side of the bracket, the input ends of one group of conveying rollers extend to the front side of the bracket, a group of chain wheels are arranged at the output ends of each group of conveying rollers, the chain is coated and arranged on the plurality of groups of chain wheels, the motor I is arranged at the front end of the bracket, and the output end of the motor I is connected with the input end of one group of conveying rollers; the motor is turned on to drive the pair of conveying rollers, so that the conveying rollers are matched with the chain wheels to rotate with the chains to convey materials.

Preferably, the laminating mechanism comprises two groups of telescopic cylinders, a press roller and two groups of material rollers, wherein the two groups of telescopic cylinders are arranged at the lower end of the bracket, the press roller is rotatably arranged at the lower end of the two groups of telescopic cylinders, and the two groups of material rollers are rotatably arranged on the bracket; the glass film is arranged on the material roller, and the compression roller is used for pushing down the glass to cover the glass film.

Preferably, the heating mechanism comprises a heating bin, a fan, two groups of first nozzles and an air pipe I, the heating bin is arranged at the front end of the bracket, the fan is arranged at the front end of the heating bin, the two groups of first nozzles are arranged on the bracket, and the input ends of the two groups of first nozzles are communicated with the inside of the heating bin through the air pipe I; the heating bin is opened to heat air, and the fan is opened to enable hot air in the heating bin to be sprayed out through the first air pipe matching nozzle to heat the glass film.

Preferably, the electric removing mechanism comprises an electric removing liquid bin, a pump, two groups of spray heads, a water pipe and two groups of scrapers, wherein the electric removing liquid bin is arranged at the lower end of the bracket, the pump is arranged at the front end of the electric removing liquid bin, the input end of the pump extends to the inner side of the electric removing liquid bin, the two groups of spray heads are arranged on the bracket, the input ends of the two groups of spray heads are connected with the output end of the pump through the water pipe, and the two groups of scrapers are arranged on the bracket; the pump is opened to cooperate with the spray head to spray the de-electrification liquid through the water pipe to de-electrify the glass, and the de-electrification liquid on the glass is scraped through the scraping plate.

Preferably, the drying mechanism comprises two groups of nozzles II and an air pipe II, the two groups of nozzles II are arranged on the bracket, and the input ends of the two groups of nozzles II are communicated with the inside of the heating bin through the air pipe II; and (3) spraying hot air in the heating bin through the second nozzle to dry the glass.

Preferably, the cutting mechanism comprises a sliding block, a second motor, a gear, a rack, a cylinder and a cutter, wherein the sliding block is slidably arranged on the bracket, the second motor is arranged at the upper end of the sliding block, the gear is connected with the output end of the second motor, the rack is arranged at the upper end of the bracket, the rack is meshed with the gear, the cylinder is arranged at the lower end of the sliding block, and the cutter is rotatably arranged on the cylinder; the cutter descends by opening the air cylinder, the gear is rotated by opening the motor II to drive the gear, and the gear is meshed with the rack to move the sliding block when rotating, so that the cutter cuts materials.

Compared with the prior art, the utility model has the beneficial effects that: through opening transport mechanism and transporting the material, remove the electric mechanism through opening and remove the work of destaticizing to the material, make drying mechanism dry the material through heating mechanism simultaneously, carry out the tectorial membrane through opening tectorial membrane mechanism to the material, heat the tectorial membrane through opening heating mechanism simultaneously, cut the material after the processing is accomplished through opening cutting mechanism to make glass tectorial membrane in-process, not only can carry out two-sided tectorial membrane to the material, can also remove the electric dust to the material, improve machining efficiency.

Drawings

FIG. 1 is a schematic view of a first axial structure of the present utility model;

FIG. 2 is a schematic view of a second axial structure of the present utility model;

FIG. 3 is a schematic illustration of a first elevation cross-sectional isometric construction of the present utility model;

FIG. 4 is a schematic diagram of a second elevation cross-sectional isometric construction of the present utility model;

FIG. 5 is a schematic view of a left-hand cross-sectional axially-measured structure of the present utility model;

The reference numerals in the drawings: 1. a transport mechanism; 11. a bracket; 12. a transport roller; 13. a sprocket; 14. a chain; 15. a first motor; 2. a film covering mechanism; 21. a telescopic cylinder; 22. a press roller; 23. a material roller; 3. a heating mechanism; 31. a heating bin; 32. a blower; 33. a first nozzle; 34. an air pipe I; 4. a de-motor mechanism; 41. a dehydrating liquid bin; 42. a pump machine; 43. a spray head; 44. a water pipe; 45. a scraper; 5. a drying mechanism; 51. a second nozzle; 52. an air pipe II; 6. a cutting mechanism; 61. a slide block; 62. a second motor; 63. a gear; 64. a rack; 65. a cylinder; 66. and (5) a cutter.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. This utility model may be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Example 1

As shown in fig. 1 to 5, the device comprises a conveying mechanism 1, and further comprises a film covering mechanism 2, a heating mechanism 3, a removing mechanism 4, a drying mechanism 5 and a cutting mechanism 6, wherein the film covering mechanism 2 is arranged on the conveying mechanism 1, the heating mechanism 3 is arranged at the front end of the conveying mechanism 1, the removing mechanism 4 is arranged at the lower end of the conveying mechanism 1, the drying mechanism 5 is arranged on the conveying mechanism 1, and the cutting mechanism 6 is arranged on the conveying mechanism 1;

The conveying mechanism 1 conveys, the film coating mechanism 2 coats films, the heating mechanism 3 heats, the static electricity removing mechanism 4 removes static electricity, the drying mechanism 5 dries and the cutting mechanism 6 cuts;

The conveying mechanism 1 comprises a bracket 11, a plurality of groups of conveying rollers 12, a plurality of groups of chain wheels 13, a chain 14 and a motor I15, wherein the plurality of groups of conveying rollers 12 are rotatably arranged on the bracket 11, the output ends of the plurality of groups of conveying rollers 12 extend to the rear side of the bracket 11, the input ends of one group of conveying rollers 12 extend to the front side of the bracket 11, a group of chain wheels 13 are arranged at the output ends of each group of conveying rollers 12, the chain 14 is coated and arranged on the plurality of groups of chain wheels 13, the motor I15 is arranged at the front end of the bracket 11, and the output ends of the motor I15 are connected with the input ends of one group of conveying rollers 12;

The laminating mechanism 2 comprises two groups of telescopic cylinders 21, a press roll 22 and two groups of material rolls 23, wherein the two groups of telescopic cylinders 21 are arranged at the lower end of the bracket 11, the press roll 22 is rotatably arranged at the lower end of the two groups of telescopic cylinders 21, and the two groups of material rolls 23 are rotatably arranged on the bracket 11;

The heating mechanism 3 comprises a heating bin 31, a fan 32, two groups of first nozzles 33 and a first air pipe 34, the heating bin 31 is arranged at the front end of the bracket 11, the fan 32 is arranged at the front end of the heating bin 31, the two groups of first nozzles 33 are arranged on the bracket 11, and the input ends of the two groups of first nozzles 33 are communicated with the inside of the heating bin 31 through the first air pipe 34;

The cutting mechanism 6 comprises a sliding block 61, a second motor 62, a gear 63, a rack 64, a cylinder 65 and a cutter 66, wherein the sliding block 61 is slidably arranged on the bracket 11, the second motor 62 is arranged at the upper end of the sliding block 61, the gear 63 is connected with the output end of the second motor 62, the rack 64 is arranged at the upper end of the bracket 11, the rack 64 is meshed with the gear 63, the cylinder 65 is arranged at the lower end of the sliding block 61, and the cutter 66 is rotatably arranged on the cylinder 65;

The first motor 15 is turned on to drive the conveying roller 12 to rotate by matching with the chain wheel 13 and the chain 14 to convey materials, the glass film is installed on the material roller 23, the compression roller 22 is pressed down by the telescopic cylinder 21 to cover the glass film on the glass, meanwhile, the heating bin 31 is turned on to heat air, the first fan 32 is turned on to enable hot air in the heating bin 31 to be sprayed out by the first air pipe 34 matched with the first nozzle 33 to heat the glass film, the air cylinder 65 is turned on to enable the cutter 66 to descend, the second motor 62 is turned on to drive the gear 63 to rotate, the gear 63 rotates and simultaneously is meshed with the rack 64 to enable the slider 61 to move, so that the cutter 66 cuts the materials, and in the glass film coating process, double-sided film coating can be carried out on the materials, and the processing efficiency is improved.

Example 2

As shown in fig. 1 to 5, the device comprises a conveying mechanism 1, and further comprises a film covering mechanism 2, a heating mechanism 3, a removing mechanism 4, a drying mechanism 5 and a cutting mechanism 6, wherein the film covering mechanism 2 is arranged on the conveying mechanism 1, the heating mechanism 3 is arranged at the front end of the conveying mechanism 1, the removing mechanism 4 is arranged at the lower end of the conveying mechanism 1, the drying mechanism 5 is arranged on the conveying mechanism 1, and the cutting mechanism 6 is arranged on the conveying mechanism 1;

The conveying mechanism 1 conveys, the film coating mechanism 2 coats films, the heating mechanism 3 heats, the static electricity removing mechanism 4 removes static electricity, the drying mechanism 5 dries and the cutting mechanism 6 cuts;

The conveying mechanism 1 comprises a bracket 11, a plurality of groups of conveying rollers 12, a plurality of groups of chain wheels 13, a chain 14 and a motor I15, wherein the plurality of groups of conveying rollers 12 are rotatably arranged on the bracket 11, the output ends of the plurality of groups of conveying rollers 12 extend to the rear side of the bracket 11, the input ends of one group of conveying rollers 12 extend to the front side of the bracket 11, a group of chain wheels 13 are arranged at the output ends of each group of conveying rollers 12, the chain 14 is coated and arranged on the plurality of groups of chain wheels 13, the motor I15 is arranged at the front end of the bracket 11, and the output ends of the motor I15 are connected with the input ends of one group of conveying rollers 12;

The laminating mechanism 2 comprises two groups of telescopic cylinders 21, a press roll 22 and two groups of material rolls 23, wherein the two groups of telescopic cylinders 21 are arranged at the lower end of the bracket 11, the press roll 22 is rotatably arranged at the lower end of the two groups of telescopic cylinders 21, and the two groups of material rolls 23 are rotatably arranged on the bracket 11;

The heating mechanism 3 comprises a heating bin 31, a fan 32, two groups of first nozzles 33 and a first air pipe 34, the heating bin 31 is arranged at the front end of the bracket 11, the fan 32 is arranged at the front end of the heating bin 31, the two groups of first nozzles 33 are arranged on the bracket 11, and the input ends of the two groups of first nozzles 33 are communicated with the inside of the heating bin 31 through the first air pipe 34;

The de-electric mechanism 4 comprises a de-electrohydraulic cabin 41, a pump 42, two groups of spray heads 43, a water pipe 44 and two groups of scrapers 45, wherein the de-electrohydraulic cabin 41 is arranged at the lower end of the bracket 11, the pump 42 is arranged at the front end of the de-electrohydraulic cabin 41, the input end of the pump 42 extends to the inner side of the de-electrohydraulic cabin 41, the two groups of spray heads 43 are arranged on the bracket 11, the input ends of the two groups of spray heads 43 are connected with the output end of the pump 42 through the water pipe 44, and the two groups of scrapers 45 are arranged on the bracket 11;

The drying mechanism 5 comprises two groups of nozzles II 51 and an air duct II 52, the two groups of nozzles II 51 are arranged on the bracket 11, and the input ends of the two groups of nozzles II 51 are communicated with the inside of the heating bin 31 through the air duct II 52;

The cutting mechanism 6 comprises a sliding block 61, a second motor 62, a gear 63, a rack 64, a cylinder 65 and a cutter 66, wherein the sliding block 61 is slidably arranged on the bracket 11, the second motor 62 is arranged at the upper end of the sliding block 61, the gear 63 is connected with the output end of the second motor 62, the rack 64 is arranged at the upper end of the bracket 11, the rack 64 is meshed with the gear 63, the cylinder 65 is arranged at the lower end of the sliding block 61, and the cutter 66 is rotatably arranged on the cylinder 65;

The first motor 15 is turned on to drive the conveying roller 12 to rotate the conveying roller 12, the sprocket 13 and the chain 14 are matched, the pump 42 is turned on to spray the electro-removing liquid through the water pipe 44, the electro-removing liquid is sprayed out to remove electricity from glass, the scraping plate 45 is used for scraping the electro-removing liquid on the glass, the second nozzle 51 is turned on to spray hot air in the heating bin 31 to dry the glass, the glass film is arranged on the material roller 23, the compression roller 22 is pressed down to cover the glass by the glass through the telescopic cylinder 21, the heating bin 31 is turned on to heat the air, the first fan 32 is turned on to spray hot air in the heating bin 31 through the first air pipe 34 and spray the nozzle 33 to heat the glass film, the air cylinder 65 is turned on to descend the cutter 66, the second motor 62 is turned on to drive the gear 63 to rotate the gear 63, and the gear 63 rotates simultaneously with the rack 64

The engagement makes the slider 61 move, so that the cutter 66 cuts the material, and in the process of coating the glass film, the material can be subjected to electric precipitation and dust removal, and the processing efficiency is improved.

As shown in fig. 1 to 5, in the automatic glass laminating apparatus of the present utility model, during operation, the first motor 15 is turned on to drive the conveying roller 12 to rotate in cooperation with the sprocket 13 and the chain 14, the first pump 42 is turned on to discharge the removing liquid through the water pipe 44 in cooperation with the nozzle 43 to remove electricity from the glass, the removing liquid on the glass is scraped by the scraper 45, the hot air in the heating chamber 31 is discharged through the nozzle second 51 to dry the glass, the glass film is mounted on the material roller 23, the compression roller 22 is pressed down to coat the glass film on the glass by the compression roller 22, the heating chamber 31 is turned on to heat the air, the first fan 32 is turned on to heat the hot air in the heating chamber 31 through the first air pipe 34 in cooperation with the nozzle first 33, the cutter 66 is lowered by turning on the cylinder 65, the second motor 62 is turned on to rotate the gear 63, and the gear 63 is rotated while the gear 63 is meshed with the rack 64 to move the slider 61, thereby cutting the material by the cutter 66.

The motor one 15, fan 32, pump 42, motor two 62 and cylinder 65 of the present utility model are commercially available and will be installed and operated by those skilled in the art in light of their attendant instructions without the need for inventive labor by those skilled in the art.

The main functions realized by the utility model are as follows: in the automatic glass film coating working process, the film coating mechanism and the electric removing mechanism are arranged, so that the double-sided film coating can be carried out on materials, the electric removing and dust removing can be carried out on the materials, and the processing efficiency is improved.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (7)

1. An automatic glass laminating device comprises a conveying mechanism (1); the device is characterized by further comprising a film covering mechanism (2), a heating mechanism (3), a motor removing mechanism (4), a drying mechanism (5) and a cutting mechanism (6), wherein the film covering mechanism (2) is arranged on the conveying mechanism (1), the heating mechanism (3) is arranged at the front end of the conveying mechanism (1), the motor removing mechanism (4) is arranged at the lower end of the conveying mechanism (1), the drying mechanism (5) is arranged on the conveying mechanism (1), and the cutting mechanism (6) is arranged on the conveying mechanism (1);

The conveying mechanism (1) conveys, the film coating mechanism (2) coats films, the heating mechanism (3) heats, the static electricity removing mechanism (4) removes static electricity, the drying mechanism (5) dries, and the cutting mechanism (6) cuts.

2. An automatic glass laminating apparatus according to claim 1, wherein the transport mechanism (1) comprises a bracket (11), a plurality of sets of transport rollers (12), a plurality of sets of chain wheels (13), a chain (14) and a motor one (15), the plurality of sets of transport rollers (12) are rotatably mounted on the bracket (11), and the output ends of the plurality of sets of transport rollers (12) all extend to the rear side of the bracket (11), the input ends of one set of transport rollers (12) extend to the front side of the bracket (11), the output ends of each set of transport rollers (12) are each mounted with a set of chain wheels (13), the chain (14) is mounted on the plurality of sets of chain wheels (13) in a wrapping manner, the motor one (15) is mounted at the front end of the bracket (11), and the output end of the motor one (15) is connected with the input ends of the one set of transport rollers (12).

3. An automatic glass laminating apparatus as claimed in claim 2, wherein the laminating mechanism (2) comprises two sets of telescopic cylinders (21), a press roller (22) and two sets of material rollers (23), wherein the two sets of telescopic cylinders (21) are mounted at the lower ends of the brackets (11), the press roller (22) is rotatably mounted at the lower ends of the two sets of telescopic cylinders (21), and the two sets of material rollers (23) are rotatably mounted on the brackets (11).

4. An automatic glass laminating device as claimed in claim 2, wherein the heating mechanism (3) comprises a heating chamber (31), a fan (32), two groups of first nozzles (33) and a first air duct (34), the heating chamber (31) is arranged at the front end of the bracket (11), the fan (32) is arranged at the front end of the heating chamber (31), the two groups of first nozzles (33) are arranged on the bracket (11), and the input ends of the two groups of first nozzles (33) are communicated with the inside of the heating chamber (31) through the first air duct (34).

5. An automatic glass laminating apparatus according to claim 2, wherein the electro-removing mechanism (4) comprises an electro-removing liquid chamber (41), a pump (42), two groups of spray nozzles (43), a water pipe (44) and two groups of scrapers (45), the electro-removing liquid chamber (41) is mounted at the lower end of the support (11), the pump (42) is mounted at the front end of the electro-removing liquid chamber (41), the input end of the pump (42) extends to the inner side of the electro-removing liquid chamber (41), the two groups of spray nozzles (43) are mounted on the support (11), and the input ends of the two groups of spray nozzles (43) are connected with the output end of the pump (42) through the water pipe (44), and the two groups of scrapers (45) are mounted on the support (11).

6. An automatic glass laminating device as claimed in claim 2, wherein the drying mechanism (5) comprises two groups of nozzles (51) and an air duct (52), the two groups of nozzles (51) are arranged on the bracket (11), and the input ends of the two groups of nozzles (51) are communicated with the interior of the heating bin (31) through the air duct (52).

7. An automatic glass laminating apparatus according to claim 2, wherein the cutting mechanism (6) comprises a slider (61), a motor two (62), a gear (63), a rack (64), a cylinder (65) and a cutter (66), the slider (61) is slidably mounted on the bracket (11), the motor two (62) is mounted on the upper end of the slider (61), the gear (63) is connected with the output end of the motor two (62), the rack (64) is mounted on the bracket (11), and the rack (64) is engaged with the gear (63), the cylinder (65) is mounted on the lower end of the slider (61), and the cutter (66) is rotatably mounted on the cylinder (65).