CN210062310U

CN210062310U - Efficient laminating device for touch film processing

Info

Publication number: CN210062310U
Application number: CN201920450573.2U
Authority: CN
Inventors: 刘泽江; 张军
Original assignee: UC Nano Technologies Inc
Current assignee: Hefei Yuandun Sensor Technology Co ltd
Priority date: 2019-04-04
Filing date: 2019-04-04
Publication date: 2020-02-14
Anticipated expiration: 2029-04-04

Abstract

The utility model discloses a processing of touch-control membrane is with high-efficient tectorial membrane device, including the frame, install second transport module, third transport module and the operation board in the frame, third transport module includes two parallel mount supporting beam, motor in the frame, sets up in two action wheels of a supporting beam one end, is located two of a supporting beam other end from driving wheel and conveyer belt, second transport module further includes the fixed plate of being connected with the frame, is located the fly leaf of fixed plate top, parallel mount two installation curb plates of fly leaf upper surface, installs the conveying motor on the fly leaf and installs the driving motor in the fixed plate lower surface, installs a tectorial membrane mechanism in the frame of second transport module top, and this tectorial membrane mechanism further includes mount pad, blowing roller bearing, receives membrane roller bearing and separation roller bearing. The utility model discloses an automation of touch-control membrane substrate cuts, transports and prints, replaces the manual work, practices thrift the labour in a large number, has improved precision and efficiency to touch-control membrane processing.

Description

Efficient laminating device for touch film processing

Technical Field

The utility model relates to a processing of touch-control membrane is with high-efficient tectorial membrane device belongs to touch-control technical field.

Background

With the wide popularization and application of computer technology, the way of electronization and digitization of information is more and more abundant. People use various peripherals of computers to implement various methods to complete the initial digitization of information processing. For example: the most effective and most convenient one of various keyboard input methods, voice input, image acquisition and the like is information input and instruction transferring directly through touch clicking and other modes. For example, when drawing a drawing with a computer, the operation with a mouse is not really as flexible as the operation of drawing a drawing on a paper surface with a pen, and thus the skilled completion of fine pattern making is always prevented. The touch screen is directly operated by hand touch, and the action is just like drawing on a paper surface, so that the whole work is very easy to finish, and the effect is better. Furthermore, with the continued push-out of portable products, various peripherals: the keyboard and the mouse are omitted one by one, for example, a PDA (personal digital assistant) basically has no key operation, and the touch control pen is adopted to operate the touch screen to complete various operations.

The existing small-size liquid crystal touch screen cannot represent rich and colorful multimedia applications due to small picture and weak expressive force, while the large-size liquid crystal touch screen limits the application of the large-size liquid crystal touch screen due to factors such as large power consumption, space occupation, high price and the like.

The appearance of the projection imaging film and the electromagnetic induction touch film solves the defect of a large-size touch liquid crystal screen, but the traditional ITO film is brittle and not suitable for bendable application, and the essential problems of conductivity, light transmittance and the like on a flexible substrate are not easy to overcome. Silver nanowire conductive films are attracting more and more attention due to the advantages of flexibility, low cost, low resistance and high light transmittance.

The nanometer touch control film is an induction film mainly used for packaging nanometer wires, integrates multiple functions of accurate induction positioning, flexibility, high transparency and the like, is used for accurate touch control positioning of a touch control screen of more than 10 inches, and is also applied to accurate interactive projection and security positioning. At present, the equipment that can independent complete large-scale production nanometer touch membrane still does not exist in the market, and its production still is in the lab scale stage, and its equipment and instruments are mostly experimental precision equipment, and the price is expensive, and manufacturing cost is high, and secondly, because the limitation of equipment, operating procedure is more complicated, and assembly line production is difficult, extravagant manpower and materials, and the yield is difficult to control.

Disclosure of Invention

The utility model aims at providing a touch-control membrane processing is with high-efficient tectorial membrane device, this touch-control membrane processing is with high-efficient tectorial membrane device have realized that the automation of touch-control membrane substrate cuts, transports and prints, replace the manual work, practice thrift the labour in a large number, have improved precision and efficiency to touch-control membrane processing.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a high-efficiency film laminating device for processing a touch control film comprises a rack, a second conveying module, a third conveying module and an operation board, wherein the second conveying module, the third conveying module and the operation board are arranged on the rack;

the third conveying module comprises two supporting beams which are arranged on the rack in parallel, a motor, two driving wheels arranged at one end of each supporting beam, two driven wheels arranged at the other end of each supporting beam and a conveying belt, the driving wheels and the driven wheels at the two ends of the same supporting beam are in transmission connection through the conveying belts, the two driving wheels are connected through a synchronizing shaft, and the synchronizing shaft is connected with an output shaft of the motor;

the second transmission module further comprises a fixed plate connected with the frame, a movable plate positioned above the fixed plate, two mounting side plates arranged on the upper surface of the movable plate in parallel, a transmission motor arranged on the movable plate and a driving motor arranged on the lower surface of the fixed plate, two screw rods are connected between the fixed plate and the movable plate, the lower ends of the screw rods sequentially penetrate through holes in the movable plate and the fixed plate and are connected with the fixed plate through a bearing, a rotating wheel is arranged at the tail end of each screw rod, the rotating wheels at the tail ends of the two screw rods are connected through a synchronous belt, a driving wheel is arranged on the screw rod above any one rotating wheel and is connected with a belt pulley arranged on an output shaft of the driving motor through a belt, a nut is sleeved on each screw rod and is fixedly connected with the movable plate;

a first driving wheel is mounted on an output shaft of the conveying motor, the first driving wheel is connected with a first driven wheel mounted on a rotating shaft through a driving belt, two ends of the rotating shaft respectively penetrate through the mounting side plate and are rotatably connected with a bearing mounting seat, a second driven wheel is mounted at two ends of the rotating shaft and positioned on the inner side of the mounting side plate respectively, a plurality of conveying wheels are rotatably mounted on the inner side of the mounting side plate, and the conveying wheel and the second driven wheel positioned on the same side are connected through a conveying belt;

install a tectorial membrane mechanism in the frame of second conveying module top, this tectorial membrane mechanism further includes mount pad, blowing roller bearing, receives membrane roller bearing and separation roller bearing, blowing roller bearing and receipts membrane roller bearing parallel mount are in the one end of mount pad third conveying module mutually in the back of the body, the separation roller bearing is rotationally installed in the other end of mount pad, install a blowing motor on a curb plate of mount pad, this blowing motor is used for driving the blowing roller bearing rotatory, install one on the curb plate of mount pad and receive the membrane motor, this receipts membrane motor is used for the drive to receive the membrane roller bearing rotatory, be provided with one between tectorial membrane mechanism and the third conveying module and cut out membrane mechanism, third conveying module top is provided with a triaxial printing device.

The further improved scheme in the technical scheme is as follows:

1. in the scheme, the mounting seat is further provided with the film pressing rollers in parallel.

2. In the above scheme, the plurality of conveying wheels are arranged at equal intervals.

3. In the scheme, the number of the conveying wheels is 4-8.

4. In the above scheme, the driving wheels are installed at two ends of the synchronizing shaft.

5. In the above scheme, two parallel arrangement's two mounting panels are all installed at a supporting beam's both ends, the action wheel all sets up between two mounting panels with from the driving wheel.

6. In the above scheme, at least two guide pillars are further arranged between the movable plate and the fixed plate, and the lower ends of the guide pillars penetrate through the through holes in the movable plate and are fixedly connected with the upper surface of the fixed plate.

7. In the above scheme, the guide post is connected with the through hole on the movable plate through a bearing seat.

8. In the above scheme, the number of the guide posts is 4, and the guide posts are respectively positioned at four corners of the movable plate or the fixed plate.

9. In the above scheme, the length of the guide post is equal to that of the screw rod.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses high-efficient tectorial membrane device is used in touch-control membrane processing, it is through the setting of driving motor and lead screw, has realized the upper and lower drive to the fly leaf, through the reciprocating of fly leaf, realizes reciprocating to the operation board of placing on the fly leaf, is convenient for to the processing of product on the operation board; in addition, the two screw rods are synchronously driven to rotate by one motor, the synchronization rate is high, the precision and the stability of driving the movable plate are ensured, and resources and equipment space are saved; in addition, the arrangement of the conveying belt realizes the conveying of the operation plate on the movable plate in the horizontal direction, realizes the conveying of the operation plate in the horizontal and vertical directions to completely replace manpower, and provides the production efficiency; and the setting of a plurality of transfer pulleys in the below of conveyer belt had both guaranteed the drive power that transports at the horizontal direction to the operation board, has provided the ascending holding power of vertical direction again, has guaranteed the stability in the operation board transportation process.

2. The utility model discloses touch-control membrane processing is with high-efficient tectorial membrane device, its tectorial membrane mechanism cooperation is cut out membrane mechanism, each transport module and triaxial printing device, has realized that the automation of touch-control membrane substrate cuts, transports and prints, replaces the manual work, practices thrift the labour in a large number, has improved precision and efficiency to touch-control membrane processing.

3. The utility model discloses touch-control membrane processing is with high-efficient tectorial membrane device, the setting of its guide post plays spacing and the effect of direction to the fly leaf, guarantees its position precision on the horizontal direction at the in-process that the fly leaf reciprocated, and further assurance to the precision of transporting of the operation platform on the fly leaf to and follow-up machining precision to the operation bench product.

Drawings

FIG. 1 is a schematic structural view of the high-efficiency laminating device for processing touch films of the present invention;

fig. 2 is a front view of the high-efficiency laminating device for processing a touch film of the present invention;

FIG. 3 is a schematic view of a third transfer module of the film covering device according to the present invention;

FIG. 4 is a schematic view of a partial structure of a second transfer module in the film covering device of the present invention;

FIG. 5 is a schematic structural view of a second transfer module in the film covering device of the present invention;

FIG. 6 is a schematic view of a partial structure of a film covering mechanism in the film covering device of the present invention;

fig. 7 is the utility model discloses tectorial membrane mechanism schematic diagram among touch-control membrane processing is with high-efficient tectorial membrane device.

In the above drawings: 1. a frame; 3. a second transfer module; 4. a third transfer module; 5. an operation plate; 11. a support beam; 12. a motor; 13. a driving wheel; 14. a driven wheel; 15. a conveyor belt; 16. a synchronizing shaft; 17. mounting a plate; 21. a fixing plate; 22. a movable plate; 23. installing a side plate; 24. a transfer motor; 25. a drive motor; 26. a screw rod; 27. a rotating wheel; 28. a synchronous belt; 29. a drive wheel; 30. a belt pulley; 31. a belt; 32. a nut; 33. a guide post; 34. a bearing seat; 35. a first drive wheel; 36. a rotating shaft; 37. a first driven wheel; 38. a transmission belt; 39. a bearing mount; 40. a second driven wheel; 41. a transfer wheel; 42. a conveyor belt; 56. a film covering mechanism; 57. a mounting seat; 58. a discharging roller; 59. a film collecting roller; 60. a discharging motor; 61. a film collecting motor; 62. a film pressing roller; 67. a film cutting mechanism; 68. a three-axis printing device; 69. the roller is separated.

Detailed Description

Example 1: a high-efficiency film laminating device for processing a touch control film comprises a rack 1, a second conveying module 3, a third conveying module 4 and a working plate 5, wherein the second conveying module 3, the third conveying module 4 and the working plate 5 are installed on the rack 1, the working plate 5 is conveyed between the second conveying module 3 and the third conveying module 4, and the second conveying module 3 is located on one side of the third conveying module 4;

the third transmission module 4 comprises two support beams 11 which are arranged on the frame 1 in parallel, a motor 12, two driving wheels 13 arranged at one end of each support beam 11, two driven wheels 14 arranged at the other end of each support beam 11 and a transmission belt 15, wherein the driving wheels 13 and the driven wheels 14 arranged at two ends of the same support beam 11 are in transmission connection through the transmission belt 15, the two driving wheels 13 are connected through a synchronizing shaft 16, and the synchronizing shaft 16 is connected with an output shaft of the motor 12;

the second transmission module 3 further comprises a fixed plate 21 connected with the frame 1, a movable plate 22 positioned above the fixed plate 21, two mounting side plates 23 mounted on the upper surface of the movable plate 22 in parallel, a transmission motor 24 mounted on the movable plate 22, and a driving motor 25 mounted on the lower surface of the fixed plate 21, two lead screws 26 are connected between the fixed plate 21 and the movable plate 22, the lower ends of the lead screws 26 sequentially pass through holes on the movable plate 22 and the fixed plate 21 and are connected with the fixed plate 21 through a bearing, a rotating wheel 27 is mounted at the tail end of each lead screw 26, the rotating wheels 27 at the tail ends of the two lead screws 26 are connected through a synchronous belt 28, a driving wheel 29 is mounted on the lead screw 26 above any one rotating wheel 27, the driving wheel 29 is connected with a belt pulley 30 mounted on an output shaft of the driving motor 25 through a belt 31, the nut 32 is fixedly connected with the movable plate 22, and the top end of the screw rod 26 is connected with the frame 1;

a first driving wheel 35 is mounted on an output shaft of the transmission motor 24, the first driving wheel 35 is connected with a first driven wheel 37 mounted on a rotating shaft 36 through a transmission belt 38, two ends of the rotating shaft 36 respectively penetrate through the mounting side plate 23 and are rotatably connected with a bearing mounting seat 39, a second driven wheel 40 is respectively mounted at two ends of the rotating shaft 36 and positioned on the inner side of the mounting side plate 23, a plurality of transmission wheels 41 are rotatably mounted on the inner side of the mounting side plate 23, and the transmission wheel 41 and the second driven wheel 40 positioned on the same side are connected through a transmission belt 42;

install a tectorial membrane mechanism 56 on the frame 1 of second conveying module 3 top, this tectorial membrane mechanism 56 further includes mount pad 57, blowing roller 58, receives membrane roller 59 and separation roller 69, blowing roller 58 and receipts membrane roller 59 parallel mount are in the one end of mount pad 57 back to the third conveying module 4, separation roller 69 rotationally installs in the other end of mount pad 57, install a blowing motor 60 on a curb plate of mount pad 57, this blowing motor 60 is used for driving blowing roller 58 rotatory, install one on the curb plate of mount pad 57 and receive membrane motor 61, this receipts membrane motor 61 is used for driving and receives the rotation of membrane roller 59, be provided with a cutting mechanism 67 between tectorial membrane mechanism 56 and the third conveying module 4, be provided with a triaxial printing device 68 above the third conveying module 4.

A plurality of film pressing rollers 62 are arranged on the mounting seat 57 in parallel; the plurality of transmission wheels 41 are arranged at equal intervals; the number of the plurality of conveying wheels 41 is 6; the driving wheels 13 are arranged at two ends of the synchronizing shaft 16; two parallel mounting plates 17 are mounted at two ends of the supporting beam 11, and the driving wheel 13 and the driven wheel 14 are both arranged between the two mounting plates 17.

Example 2: a high-efficiency film laminating device for processing a touch control film comprises a rack 1, a second conveying module 3, a third conveying module 4 and a working plate 5, wherein the second conveying module 3, the third conveying module 4 and the working plate 5 are installed on the rack 1, the working plate 5 is conveyed between the second conveying module 3 and the third conveying module 4, and the second conveying module 3 is located on one side of the third conveying module 4;

At least two guide posts 33 are further disposed between the movable plate 22 and the fixed plate 21, and the lower ends of the guide posts 33 pass through the through holes of the movable plate 22 and are fixedly connected with the upper surface of the fixed plate 21; the guide post 33 is connected with the through hole of the movable plate 22 through a bearing seat 34; the number of the guide posts 33 is 4, and the guide posts are respectively positioned at four corners of the movable plate 22 or the fixed plate 21; the length of the guide post 33 is equal to the length of the lead screw 26.

When the efficient laminating device for processing the touch control film is adopted, the movable plate is driven up and down through the arrangement of the driving motor and the screw rod, the movable plate is moved up and down through the up and down movement of the movable plate, the up and down movement of the operation plate placed on the movable plate is realized, and the processing of products on the operation plate is facilitated; in addition, the two screw rods are synchronously driven to rotate by one motor, the synchronization rate is high, the precision and the stability of driving the movable plate are ensured, and resources and equipment space are saved;

in addition, the arrangement of the conveying belt realizes the conveying of the operation plate on the movable plate in the horizontal direction, realizes the conveying of the operation plate in the horizontal and vertical directions to completely replace manpower, and provides the production efficiency; the arrangement of the plurality of conveying wheels below the conveying belt ensures the driving force for conveying the operation plate in the horizontal direction, provides the supporting force in the vertical direction and ensures the stability in the conveying process of the operation plate;

in addition, the film laminating mechanism is matched with the film cutting mechanism, each conveying module and the three-axis printing device, so that automatic cutting, conveying and printing of the touch film substrate are realized, manual work is replaced, labor force is greatly saved, and the precision and efficiency of touch film processing are improved;

in addition, the guide columns play a role in limiting and guiding the movable plate, the position precision of the movable plate in the horizontal direction is guaranteed in the up-and-down moving process of the movable plate, the conveying precision of the operation platform on the movable plate is further guaranteed, and the subsequent processing precision of products on the operation platform is guaranteed.

When the touch film rolling device is used, the touch film substrate material cylinder with the release film is arranged on the discharging rolling shaft, the film collecting rolling shaft is used for recovering the release film stripped from the substrate, the substrate is pulled out and laid on the operation plate, the release film at the front end of the substrate is separated from the substrate by bypassing the separation rolling shaft from bottom to top and is wound on the film collecting rolling shaft, the operation plate moves forwards under the action of the transmission belt to the third transmission module, the third transmission module conveys the operation plate to a proper processing position, and then the cutting mechanism cuts open the substrate at the rear end of the operation plate and then carries out the next operation.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims

1. The utility model provides a processing of touch-control membrane is with high-efficient tectorial membrane device which characterized in that: the automatic plate feeding device comprises a rack (1), and a second conveying module (3), a third conveying module (4) and a working plate (5) which are arranged on the rack (1), wherein the working plate (5) is conveyed between the second conveying module (3) and the third conveying module (4), and the second conveying module (3) is positioned on one side of the third conveying module (4);

the third conveying module (4) comprises two supporting beams (11) which are arranged on the rack (1) in parallel, a motor (12), two driving wheels (13) arranged at one end of each supporting beam (11), two driven wheels (14) positioned at the other end of each supporting beam (11) and a conveying belt (15), wherein the driving wheels (13) and the driven wheels (14) positioned at two ends of the same supporting beam (11) are in transmission connection through the conveying belts (15), the two driving wheels (13) are connected through a synchronizing shaft (16), and the synchronizing shaft (16) is connected with an output shaft of the motor (12);

the second conveying module (3) further comprises a fixed plate (21) connected with the rack (1), a movable plate (22) positioned above the fixed plate (21), two mounting side plates (23) mounted on the upper surface of the movable plate (22) in parallel, a conveying motor (24) mounted on the movable plate (22) and a driving motor (25) mounted on the lower surface of the fixed plate (21), two lead screws (26) are connected between the fixed plate (21) and the movable plate (22), the lower ends of the lead screws (26) sequentially penetrate through holes in the movable plate (22) and the fixed plate (21) and are connected with the fixed plate (21) through a bearing, a rotating wheel (27) is mounted at the tail end of each lead screw (26), the rotating wheels (27) at the tail ends of the two lead screws (26) are connected through a synchronous belt (28), and a driving wheel (29) is mounted on the lead screw (26) above any one rotating wheel (, the driving wheel (29) is connected with a belt pulley (30) arranged on an output shaft of the driving motor (25) through a belt (31), a nut (32) is sleeved on the screw rod (26), the nut (32) is fixedly connected with the movable plate (22), and the top end of the screw rod (26) is connected with the rack (1);

a first driving wheel (35) is mounted on an output shaft of the conveying motor (24), the first driving wheel (35) is connected with a first driven wheel (37) mounted on a rotating shaft (36) through a conveying belt (38), two ends of the rotating shaft (36) respectively penetrate through the mounting side plate (23) and are rotatably connected with a bearing mounting seat (39), two ends of the rotating shaft (36) are respectively provided with a second driven wheel (40) on the inner side of the mounting side plate (23), a plurality of conveying wheels (41) are rotatably mounted on the inner side of the mounting side plate (23), and the conveying wheels (41) and the second driven wheels (40) on the same side are connected through a conveying belt (42);

a film coating mechanism (56) is installed on the rack (1) above the second conveying module (3), the film coating mechanism (56) further comprises a mounting seat (57), a discharging roller (58), a film collecting roller (59) and a separating roller (69), the discharging roller (58) and the film collecting roller (59) are installed at one end, back to the third conveying module (4), of the mounting seat (57) in parallel, the separating roller (69) is installed at the other end of the mounting seat (57) in a rotatable mode, a discharging motor (60) is installed on one side plate of the mounting seat (57), the discharging motor (60) is used for driving the discharging roller (58) to rotate, a film collecting motor (61) is installed on the side plate of the mounting seat (57), the film collecting motor (61) is used for driving the film collecting roller (59) to rotate, a film cutting mechanism (67) is arranged between the film coating mechanism (56) and the third conveying module (4), and a three-axis printing device (68) is arranged above the third conveying module (4).

2. The efficient film laminating device for processing the touch control film according to claim 1, wherein: and a plurality of film pressing rollers (62) are arranged on the mounting seat (57) in parallel.

3. The efficient film laminating device for processing the touch control film according to claim 1, wherein: the plurality of conveying wheels (41) are arranged at equal intervals.

4. The efficient film laminating device for processing the touch control film according to claim 1, wherein: the number of the plurality of conveying wheels (41) is 4-8.

5. The efficient film laminating device for processing the touch control film according to claim 1, wherein: the driving wheel (13) is arranged at two ends of the synchronizing shaft (16).

6. The efficient film laminating device for processing the touch control film according to claim 1, wherein: two parallel arrangement's two mounting panels (17) are all installed at the both ends of a supporting beam (11), action wheel (13) and follow driving wheel (14) all set up between two mounting panels (17).

7. The efficient film laminating device for processing the touch control film according to claim 1, wherein: at least two guide posts (33) are further arranged between the movable plate (22) and the fixed plate (21), and the lower ends of the guide posts (33) penetrate through the through holes in the movable plate (22) and are fixedly connected with the upper surface of the fixed plate (21).

8. The efficient film laminating device for processing the touch control film according to claim 7, wherein: the guide post (33) is connected with the through hole on the movable plate (22) through a bearing seat (34).

9. The efficient film laminating device for processing the touch control film according to claim 7, wherein: the number of the guide columns (33) is 4, and the guide columns are respectively positioned at four corners of the movable plate (22) or the fixed plate (21).

10. The efficient film laminating device for processing the touch control film according to claim 7, wherein: the length of the guide post (33) is equal to that of the screw rod (26).