CN113766735A - Thin film processing system and method - Google Patents

Abstract

The present invention provides a thin film processing system, comprising: a first glue applicator configured to form a first glue layer on a first surface of the film strip; the film belt after the first adhesive layer is formed is conveyed forwards by the driving of a first driving roller, the roller surface of the first driving roller is pressed on the first adhesive layer to form first patterns which are repeatedly arranged, and the first patterns comprise first alignment marks; the second gluing device forms a second glue layer on the second surface of the film belt from the direction of the first driving roller; the film belt after the second adhesive layer is formed is conveyed forwards by the driving of a second driving roller, the roller surface of the second driving roller is pressed on the second adhesive layer to form second patterns which are repeatedly arranged, and the second patterns comprise second alignment marks; an alignment detection device for detecting an alignment deviation between the first alignment mark and the second alignment mark; the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged within a preset deviation threshold range.

Description

Thin film processing system and method

Technical Field

The present invention relates to the field of thin film processing, and more particularly, to a thin film processing system and method.

Background

Roll-to-roll embossing devices of the prior art are typically used for single layer structure embossing. For a multilayer Flexible Printed Circuit (FPC), including a touch module, the conventional scheme is to prepare the FPC piece by piece (exposure, etching, alignment and attachment), the process efficiency is low, the folding property is poor, the line width of a large-sized Circuit is about 10 micrometers, and the problem of pollution also exists.

Because the flexible printed circuit has flexibility, it is difficult to precisely control the tension or stretching degree of the flexible printed circuit, and thus it is difficult to perform alignment in the subsequent processes of exposure, etching, alignment, and attachment.

In addition, when the film is subjected to further processing, such as alignment stamping and other steps, the required alignment accuracy is relatively high, and the current roll-to-roll stamping equipment generally has the problem that the alignment accuracy cannot meet the requirement when the roll-to-roll stamping equipment is applied to the further processing of the flexible film.

There is therefore a need for an improved thin film processing scheme.

Disclosure of Invention

The invention aims to provide a film processing system and a film processing method, which can realize accurate alignment when processing a film strip.

To achieve the object, according to one aspect of the present invention, there is provided a thin film processing system comprising: a first glue applicator configured to form a first glue layer on a first surface of the film strip; the film tape is driven by the first driving roller to be conveyed forwards, the first driving roller is provided with an embossing structure on the roller surface, and the roller surface of the first driving roller is embossed on the first adhesive layer of the film tape so as to form first patterns which are repeatedly arranged on the first adhesive layer of the film tape, wherein the first patterns comprise first alignment marks; a second glue applicator configured to form a second glue layer on a second surface of the film strip from the first drive roll direction; the second driving roller is configured to rotate controllably, the film belt formed with the second adhesive layer is conveyed forwards by the driving of the second driving roller, the second driving roller is provided with an embossing structure on the roller surface, and the roller surface of the second driving roller is embossed on the second adhesive layer of the film belt so as to form second patterns which are repeatedly arranged on the second adhesive layer of the film belt, wherein the second patterns comprise second alignment marks; the alignment detection device detects the alignment deviation of a first alignment mark of a first pattern and a second alignment mark of a second pattern on the film belt which is transmitted from the second driving roller; and the controller is configured to regulate and control the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged in a preset deviation threshold range.

According to another aspect of the present invention, there is provided a thin film processing method, comprising: the first gluing device forms a first glue layer on the first surface of the film belt; the film belt with the first adhesive layer formed is conveyed forwards by a first driving roller in a driven mode, the first driving roller is provided with an embossing structure on a roller surface, the roller surface of the first driving roller is embossed on the first adhesive layer of the film belt so as to form first patterns which are repeatedly arranged on the first adhesive layer of the film belt, and the first patterns comprise first alignment marks; the second gluing device forms a second glue layer on the second surface of the film belt from the direction of the second driving roller; the film belt with the second adhesive layer formed is conveyed forwards by a second driving roller in a driven mode, the second driving roller is provided with an embossing structure on the roller surface, the roller surface of the second driving roller is embossed on the second adhesive layer of the film belt so as to form second patterns which are repeatedly arranged on the second adhesive layer of the film belt, and the first patterns comprise second alignment marks; the alignment detection device detects the alignment deviation of a first alignment mark of a first pattern and a second alignment mark of a second pattern on the film belt transmitted from the second driving roller; the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged within a preset deviation threshold range.

Compared with the prior art, the film processing system and the film processing method have the advantages that the alignment deviation of the second alignment mark of the second pattern and the first alignment mark of the first pattern is converged within the preset deviation threshold range by regulating the rotating speed of the first driving roller and the second driving roller, so that the accurate alignment of the first pattern and the second pattern (or the area of the first pattern and the area of the second pattern) is realized.

Drawings

FIG. 1 is a schematic view of a thin film processing system according to a first embodiment of the present invention;

FIG. 2 is a schematic view of a plurality of first patterns on a film strip in accordance with the present invention;

FIG. 3 is a schematic diagram illustrating a process of forming a touch film according to an embodiment of the present invention;

FIG. 4 is a schematic view illustrating a process of forming a touch film according to another embodiment of the present invention;

FIG. 5 is a schematic view of a thin film processing system according to a second embodiment of the present invention;

FIG. 6 is a schematic view of various aspects of the film strip of the present invention during processing;

FIG. 7 is a schematic diagram of a loading assembly of the thin film processing system of the present invention in one embodiment;

FIG. 8 is a schematic view of a take-up assembly of the film processing system of the present invention in one embodiment;

fig. 9 is a schematic alignment diagram of the touch film of the present invention.

FIG. 10 is a schematic structural view of a thin film processing system according to a third embodiment of the present invention;

fig. 11 is a schematic cross-sectional view of a thin film strip during processing by the thin film processing system of fig. 10 at various steps.

Detailed Description

To further explain the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description of the embodiments, structures, features and effects according to the present invention will be given with reference to the accompanying drawings and preferred embodiments.

First embodiment of thin film processing scheme

According to one aspect of the present invention, there is provided a film processing system in which a degree of stretch of a film strip located between two drive rolls is precisely adjusted by controlling the rotation speeds of the two drive rolls.

FIG. 1 is a schematic diagram of a thin film processing system in accordance with one embodiment 100 of the present invention. As shown in fig. 1, the film processing system 100 includes a first driving roll 110, a second driving roll 120, a tension detecting device 130, and a controller 140.

The first drive roll 110 may be rotated under the control of the controller 140, and fig. 1 exemplarily shows a rotation direction R1 of the first drive roll 110, and the rotation of the first drive roll 110 may drive the film strip 200 to be conveyed forward in the direction of an arrow F1. The controller 140 may control the rotational speed and/or rotational direction of the first drive roll 110.

The second drive roll 120 may also be rotated under the control of the controller 140, and fig. 1 schematically illustrates a rotation direction R2 of the second drive roll 120, and the rotation of the second drive roll 120 may drive the film strip 200 from the first drive roll 110 to be conveyed forward in the direction of arrow F2. The controller 140 may control the rotational speed and/or the rotational direction of the second drive roll 120.

The stretch detecting device 130 is configured to detect a distance value between the positioning marks on the film strip 200 between the first drive roll 110 and the second drive roll 120. In one embodiment, the stretch detector 130 may include a photoelectric sensor that recognizes the location mark on the film strip 200 and determines the distance between the two location marks based thereon. In another embodiment, the stretch detecting device 130 may include an image capturing device, which may take a picture of the film strip 200, identify the positioning marks on the film strip 200 according to the taken picture, and determine the distance value between the positioning marks according to the identification.

The film strip 200 may be a continuous length of film, the film strip 200 having a degree of elasticity. In one embodiment, the film strip 200 may be a touch film or a raw film made into a touch film. In one embodiment, the film strip 200 includes a first pattern thereon that is repeated along a length of the film strip. Fig. 2 is a schematic diagram of a plurality of first patterns on a film strip 200 in the present invention, wherein three first patterns, 210a, 210b and 210c, are illustrated as examples, and each first pattern has a positioning mark 211, which is a line segment, therein. Of course, in other embodiments, the positioning mark may be a circle mark, a cross mark or other marks. The first pattern may be any pattern, which is not limited in the present invention. It can be seen that the distance D1 between two positioning marks 211 between two adjacent first patterns can very directly reflect the stretching degree of the film strip 200.

The controller 140 is electrically connected to the stretching detection device 130, so that the controller 140 can receive a detection signal from the stretching detection device 130, that is, a distance value detected by the stretching detection device. The controller 140 is electrically connected to the first driving roller 110 and the second driving roller 120, so that the controller 140 can send control signals to the first driving roller 110 and the second driving roller 120 to regulate and control the rotation speed and/or the rotation direction of the first driving roller 110 and the second driving roller 120. The controller 140 obtains the distance value D based on the detection of the stretching detection device 130_realThe rotation speeds of the first driving roller 110 and the second driving roller 120 are controlled so that the distance value D is obtained_realConvergence to a predetermined distance threshold range D_rangeth。

In the specific implementation, the distance value D is obtained in the detection_realGreater than the predetermined distance threshold range D_rangethAt this time, the controller 140 may regulate the rotation speeds of the first driving roller 110 and the second driving roller 120, so that the speed of the film strip 200 transmitted from the first driving roller 110 is greater than the speed of the film strip 200 transmitted from the second driving roller 120, so that the stretching degree of the film strip 200 is reduced, and thus the detected distance value D may be obtained_realDecrease; at the detected distance value D_realLess than the predetermined distance threshold range D_rangethAt this time, the controller 140 may regulate the rotation speeds of the first driving roller 110 and the second driving roller 120, so that the speed of the film strip 200 transmitted from the first driving roller 110 is lower than the speed of the film strip 200 transmitted from the second driving roller 120, so that the stretching degree of the film strip 200 is increased, and thus the detected distance value D may be obtained_realAnd is increased. Through the continuous regulation and control of the controller 140, the distance value D can be finally enabled_realConvergence to a predetermined distance threshold range D_rangeth。

In this way, by regulating and controlling the rotation speed of the first driving roller 110 and the second driving roller 120, the distance value D between the positioning marks 211 on the film strip 200 between the first driving roller and the second driving roller is enabled to be_realConvergence to a predetermined distance threshold range D_rangethThereby realizing the accurate regulation and control of the stretching degree of the film strip. Specifically, the stretching precision of the film strip 200 can be controlled within a 0.2mm error range, such as a predetermined distance threshold range D_rangethMay be 348 cm. + -. 0.01 mm.

In order to achieve a good regulation effect, the length of the film strip 200 between the first drive roll 110 and the second drive roll 120 may be set within a suitable length range. In one embodiment, the length of the film strip 200 between the first drive roll 110 and the second drive roll 120 is related to the modulus of elasticity of the film strip, the film tension, the film cross-sectional area, and the required amount of adjustment deformation, such as may satisfy the following conditions: Δ L is 1/E × L × T/S, where Δ L is a deformation amount, L is a length, T is a film tension, S is a film cross-sectional area, and E is an elastic modulus of the film. The appropriate length of the film strip 200 between the first drive roll 110 and the second drive roll 120 may allow the controller 140 to adjust the amount of deflection with sufficient precision.

In one embodiment, to set the length of the film strip 200 between the first and second drive rollers 110 and 120, the film processing system 100 may further include a roller set 160 between the first and second drive rollers 120 and 130 on the transport path of the film strip 200. The roller set 160 may include one or more transfer rollers 161, through which the film strip from the first driving roller 110 is transferred to the second driving roller 120, and the film strip passing through the one or more transfer rollers may be formed in 1 or more V-shapes. As shown in fig. 1, only one transfer roll 161 is shown, and the film web passing through the one transfer roll 161 may form 1V-shape. It should be explained here that the V-shape is a broad concept, and it is not necessary that both sides are the same inclination angle, nor that the vertex is a point, but it may be a line, i.e. a shape including many types of V-shapes. Of course, in another embodiment, the conducting roller 161 may not be provided according to the requirement, and the film strip 200 between the first driving roller 110 and the second driving roller 120 may be in a straight line shape.

In one embodiment, the thin film processing system 100 may further include: a tension roller 150 between the first drive roller 110 and the second drive roller 120 on the transport path of the film strip 200. The tension roller 150 is configured to detect a tension value of the film strip 200. The controller 140 may also be electrically connected to the tension roller 150 to receive a detection signal from the tension roller 150, i.e., a detected tension value. The controller 140 may further regulate and control the rotation speeds of the first driving roller 110 and the second driving roller 120 based on the tension value detected by the tension roller 150, so that the tension value converges to a predetermined tension threshold range. The tension roller 150 may be arranged to increase the convergence speed of the feedback system.

By adopting the film processing system provided by the invention, the stretching degree of the film belt positioned between the two driving rollers can be accurately adjusted, so that the film belt can be accurately aligned in the processes of exposure, etching, alignment, lamination and the like, and the requirements of normal industrial production are met.

According to another aspect of the present invention, the above-described thin film processing system can also be implemented as a thin film processing method. The thin film processing method comprises the following steps: the film belt is conveyed forwards sequentially through a first driving roller and a second driving roller which are driven, wherein the first driving roller and the second driving roller are configured to rotate controllably; detecting a distance value between positioning marks on a film belt between a first driving roller and a second driving roller; and regulating and controlling the rotating speeds of the first driving roller and the second driving roller based on the detected distance value, so that the distance value is converged in a preset distance threshold range.

The thin film processing method further comprises the following steps: detecting a tension value of the film belt by using a tension roller positioned between the first driving roller and the second driving roller; and regulating and controlling the rotating speeds of the first driving roller and the second driving roller based on the tension value detected by the tension roller, so that the tension value is converged in a preset tension threshold range.

Other technical contents regarding the thin film processing method can be referred to the above-mentioned description of the thin film processing system 100, and are not repeated here.

Second embodiment of thin film processing scheme

As mentioned in the background, roll-to-roll film embossing apparatus are commonly used for single layer structure embossing. For multilayer flexible circuits including touch modules, the conventional scheme is to prepare the flexible circuits one by one (exposure, etching and alignment lamination), the process efficiency is low, the folding property is poor, the line width of a large-size circuit is about 10 microns, and the efficiency is low. In the second embodiment of the present invention, a roll-to-roll process may be applied to a process for manufacturing a film strip including a touch module.

Fig. 3(d) illustrates an embodiment of a touch film. The touch film includes a base layer 311, a first holding layer 313 on the base layer, a first conductive layer 312 formed in the first holding layer 313, a second holding layer 325 on the first holding layer 313, and a second conductive layer 330 formed in the second holding layer 325, wherein the base layer 311, the first holding layer 313, and the first conductive layer 312 together constitute an initial film 310. The first retaining layer 313 may be stamped from a layer of glue and may therefore also be referred to as a glue layer. In the process of forming the touch control film, as shown in fig. 3(a), an initial film 310 may be obtained first, then as shown in fig. 3(b), a glue layer 325 'may be formed by coating on the initial film 310, then as shown in fig. 3(c), a groove 326 may be formed by imprinting on the glue layer 325', the imprinted glue layer 325 may also be referred to as a second holding layer, and finally, as shown in fig. 3(d), a second conductive layer 330 may be filled in the groove 326, so as to finally obtain the touch control film.

Fig. 4 schematically shows a forming process of the touch film in another embodiment. As shown in fig. 4(a), 4(b), 4(c) and 4(d), the formation process of the touch film in fig. 3 is substantially the same as that of the touch film in fig. 4, except that: in fig. 3, the second holding layer 325 and the second conductive layer 330 are formed on one side of the first conductive layer 312, and in fig. 4, the second holding layer 325 and the second conductive layer 330 are formed on the other side of the base layer 311, that is, the second holding layer 325 and the second conductive layer 330 are located on different sides of the base layer 311 from the first holding layer 313 and the first conductive layer 312.

In performing the groove forming step shown in fig. 3(b) and 3(c) or the groove forming step shown in fig. 4(b) and 4(c), it is necessary to consider the alignment of the pattern on the second conductive layer 330 and the pattern on the first conductive layer 312 (or the alignment of the region of the first pattern and the region of the second pattern). The pattern of the second conductive layer 330 is determined by the pattern of the recess 326, which recess forming step may also be referred to as a patterning step. However, when performing the patterning step on the initial film 310 by the roll-to-roll process, the stretching of the film strip formed on the initial film 310 is critical, since it directly determines whether the pattern to be subsequently formed on the film strip is aligned with the original pattern (the pattern formed by the first conductive layer 312).

Additionally, although fig. 3 and 4 illustrate two embodiments of touch films, other embodiments of touch films will occur to those of ordinary skill in the art in light of the teachings of the present invention. In addition, the film strip mentioned herein may be a film strip formed by the initial film 310, and may also be a film strip formed by films of other structures.

Fig. 5 is a schematic diagram of a thin film processing system 400 according to a second embodiment of the present invention. As shown in fig. 5, the film processing system 400 includes a first drive roll 410, a second drive roll 420, a stretch detector 430, a controller 440, a roll stack 460, and a tension roll 450. The operation and function of the first drive roll 410, the second drive roll 420, the tension sensing device 430, the controller 440, the roll set 460, and the tension roll 450 in fig. 5 are substantially the same as the operation and function of the first drive roll 110, the second drive roll 120, the tension sensing device 130, the controller 140, the roll set 160, and the tension roll 150 in fig. 1. To avoid repetition, this is not repeated here, and differences between the thin film processing system 400 of fig. 5 and the thin film processing system 100 of fig. 1 will be mainly described here.

The film processing system 400 in fig. 5 can not only precisely adjust the stretching degree of the film strip 510 between the two driving rollers 410 and 420, but also form an embossed layer 520 (which may also be referred to as an embossed glue layer) on the film strip 510, thereby obtaining a film strip 500 forming the embossed layer 520, wherein the cross-sectional structure of the film strip 500 outputted by the film processing system 400 is as shown in fig. 5(a), and the embossed layer 520 is formed on the original film strip 510. At times, the film strip 510 may also be referred to as a pre-treatment film strip and the film strip 500 may also be referred to as a post-treatment film strip.

As shown in connection with fig. 5 and 6, the film strip 510 is driven forward by the first drive roller 410. The strip of film 510 entering the first drive roll 410 includes a first pattern thereon that is repeated along the length of the strip of film, wherein the first pattern includes a first registration mark. As shown in fig. 6a, which shows a schematic top view of a film strip 510, two first patterns 518 are shown. Each of the first patterns 518 includes first alignment marks 512 located at four corners, a visible region 513, a bezel region 514, and a lead region 515. Of course, each first pattern 510 further includes a stretch locator mark 511, and it should be noted that, in the first embodiment described in fig. 1, the stretch locator mark 511 is referred to as a locator mark, and in the second embodiment, for distinguishing from the first alignment mark 512, it is referred to as a stretch locator mark 511. Of course, fig. 6(a) is only an example, in other examples, the first alignment marks 512 of each first pattern 510 may also be 3, 2 or more, the positions of the first alignment marks 512 may also be set as required, and the visible area 513, the frame area 514 and the lead area 515 of each first pattern 510 may also be set as required. The shape of the first alignment mark 512 is a circle with a cross, but may be other shapes. In one embodiment, the film strip 510 may be a film strip formed from the initial film 310 shown in fig. 3 and 4, wherein the pattern formed on the first conductive layer 312 is a first pattern on the first film strip 510.

As shown in fig. 5, the film processing system 400 further includes a glue applicator 472 and an alignment detector 490. The glue applicator 472 is used to form a glue layer on the film strip 510 from the direction of the first drive roll 410. In one embodiment, the applicator 472 may include a dispensing head that reciprocates to dispense the adhesive onto the film strip 510. In another embodiment, the glue applicator 472 may comprise an anilox roller which is rotated to apply glue to the film strip 510. In yet another embodiment, the glue applicator 472 includes one or more dispensing heads, each dispensing head including at least one automatic dispensing head and at least one manual dispensing head, the automatic dispensing heads being slidable to dispense glue automatically on the film strip 510; the manual dispensing head can slide to perform manual dispensing on the film strip 510.

The second driving roller 420 is provided with an embossing structure on a roller surface, and the roller surface of the second driving roller 420 is embossed on the adhesive layer of the film strip 510 to form an embossed adhesive layer, i.e., an embossed layer 520. The imprinted structures may be micro-scale structures or nano-scale structures. The second drive roll 420 may also be referred to as a plate roll.

In conjunction with fig. 5 and 6, the film tape 500 formed with the imprinting layer 520 is conveyed forward by being driven via the second driving roller 420. The imprinting layer 520 includes a second pattern that is repeated along a length of the film strip, wherein the second pattern includes a second registration mark. As shown in fig. 6(b), which shows a top view of an imprinting layer 520 formed on the thin-film strip 510. Two second patterns 528 are shown. Each of the second patterns 528 includes second alignment marks 522, a visible region 523, a rim region 524, and lead regions 525 located at four corners. Of course, fig. 6(b) is only an example, the second alignment markers 522 of each second pattern 528 may be 3, 2 or more, the positions of the second alignment markers 522 may be set according to needs, and the visible region 523, the border region 524 and the lead region 525 of each second pattern 520 may also be set according to needs. The shape of the second alignment mark 522 is a dot, but may be other shapes. In one embodiment, the imprinting layer 520 may be the second retaining layer 325, i.e., the imprinted glue layer, formed on the initial film 310 as shown in fig. 3 and 4, and the pattern formed on the second retaining layer 525 is the second pattern 528 formed on the imprinting layer 520.

The alignment detection device 490 is used to detect the alignment deviation between the first alignment mark of the first pattern and the second alignment mark of the second pattern on the film strip 510 coming out from the second driving roll 420. As shown in fig. 6(c), the first alignment mark 512 of the first pattern 518a and the second alignment mark 522 of the second pattern 528a are substantially completely aligned with an alignment offset of 0, and as shown in fig. 6(D), the first alignment mark 512 of the first pattern 518a and the second alignment mark 522 of the second pattern 528a are not aligned with an alignment offset of D2. The alignment detection device 490 may include a photo sensor, which can identify a first alignment mark of the first pattern and a second alignment mark of the second pattern, and determine an alignment deviation between the alignment marks according to the first alignment mark and the second alignment mark. In another embodiment, the alignment detection device 490 may include an image capturing device, and the image capturing device may photograph the first pattern and the second pattern, and may recognize a first alignment mark of the first pattern and a second alignment mark of the second pattern according to the photographed photographs, and determine an alignment deviation between the alignment marks according to the first alignment mark and the second alignment mark.

The controller 440 is further electrically connected to the alignment detection device 490 and receives a detection signal of the alignment detection device 490. The controller 440 may regulate the rotation speeds of the first driving roller 410 and the second driving roller 420 based on the alignment deviation obtained by the alignment detection device 490, so that the alignment deviation converges to a predetermined deviation threshold range. In a specific implementation, the alignment detection device 490 continuously detects the alignment deviation of each set of the corresponding first pattern and the corresponding second pattern, and when the current alignment deviation detected by the alignment detection device 490 exceeds a predetermined deviation threshold range, the controller 440 regulates and controls the rotation speeds of the first driving roller 410 and the second driving roller 420, and further regulates the stretching degree of the film strip 510 between the first driving roller 410 and the second driving roller 420, so as to make the alignment deviation detected subsequently closer to the predetermined deviation threshold range, and the alignment deviation converges to the predetermined deviation threshold range through one or more times of regulation and control. For example, the predetermined deviation threshold range may be 0.01mm, such that the second pattern in the imprinting layer 520 and the first pattern in the thin-film strip 510 may be aligned very precisely.

As shown in fig. 6, the first alignment marks of the first pattern include a plurality of, for example, 4, the second alignment marks of the second pattern include a plurality of, for example, 4, and the plurality of first alignment marks and the plurality of second alignment marks respectively correspond to each other. The alignment detection device 490 detects a plurality of alignment deviations of the corresponding first alignment marks and second alignment marks for a group of corresponding first patterns and second patterns, and the controller 440 regulates and controls the rotation speeds of the first driving roller 410 and the second driving roller 420, so that each alignment deviation detected for each group of corresponding first patterns and second patterns converges to a predetermined deviation threshold range.

As shown in fig. 6(c), the resulting film strip 500, with first pattern 518 and second pattern 528 aligned with one another, may form a continuous film product unit, each of which may be seen in cross-section in fig. 3(c) and 4 (c). After the conductive layer is filled on the film product unit, as shown in fig. 3(d) and 4(d), a touch film unit is formed, and finally, the touch film unit is cut from the film tape.

In the second embodiment, the controller 140 may have three feedback signals, which are the alignment deviation of the first pattern and the second pattern obtained by the alignment detection device 490, the distance value between the stretching positioning marks obtained by the stretching detection device 430, and the tension value obtained by the tension roller 450, and the controller 140 adjusts and controls the rotation speeds of the first driving roller and the second driving roller in combination with the three feedback signals, so that the three feedback signals respectively converge in the predetermined distance threshold range, the predetermined tension threshold range, and the predetermined deviation threshold range. The controller 140 may control the priority of each feedback signal being controlled in the regulation process as required, as long as the final goal can be achieved, that is, the detected alignment deviation control is converged within the predetermined deviation threshold range, and the detected distance value control is converged within the predetermined distance threshold range, and the detected tension value control is converged within the predetermined tension threshold range.

For example, the controller 140 may control the rotation speeds of the first and second driving rollers such that the detected alignment deviation converges to the predetermined deviation threshold range with a higher priority than the detected distance value converges to the predetermined distance threshold range. In other words, in order to make the alignment deviation converge within the predetermined deviation threshold range, it may be necessary to intentionally regulate the detected distance value to deviate from the predetermined distance threshold range in some periods of time so as to reduce the alignment deviation. Eventually, however, it is still necessary to regulate convergence of the detected distance value to a predetermined distance threshold range.

As shown in fig. 6(d), the first registration mark 512 is behind the second registration mark 522 (taking the film strip 500 moving from left to right as an example), and the stretching degree of the film strip 510 can be reduced by adjusting the rotation speed of the first driving roller and the second driving roller. Since the length of the second pattern 528 is equal to the circumference of the second drive roll 420, the length of the second pattern 528 is constant, the length of the first pattern 518 is shorter, and thus after a period of matching, such as after one or more overlapping alignments of the first pattern 518 and the second pattern 528, the first alignment mark 512 of the first pattern catches up with the second alignment mark 522 of the second pattern and is finally aligned. In this manner, the first few film product units on film strip 500 do not meet the top-bottom registration requirement, and as the control is completed, the film product units on film strip 500 meet the top-bottom registration requirement.

As shown in fig. 5, the thin film processing system 400 may further include: a glue roller 474 disposed behind the glue applicator 472 and adjacent to the second drive roller 420, a stripper roller 480 disposed behind the second drive roller 420 and adjacent to the second drive roller 420, and a curing device 476. The film tape forming the adhesive layer passes through the nip between the second drive roller 420 and the impression roller 474 after passing through the impression roller 474 and is conveyed to the second drive roller 420, and the film tape passes through the nip between the second drive roller 420 and the peeling roller 480 after passing through the second drive roller 420 and is conveyed to the peeling roller 480. The curing device 476 is used for curing the glue layer pressed by the second driving roller 420 on the film strip. The peeling roller 480 is used for peeling the embossed adhesive layer from the second driving roller 420, and the glue roller 474 is used for extruding the adhesive layer to make the adhesive layer more uniform. The curing device 476 may be a thermal curing device or a light curing device, such as a curing lamp, which may be a mercury lamp or an LED lamp.

It should be noted that various modifications can be made to the second embodiment of the present invention without departing from the basic idea of the second embodiment of the present invention. In an alternative embodiment, the thin film processing system 400 may not be provided with the pressure roller 450 and/or the stretch detecting device 430, and the controller 400 may control the first and second driving rollers 410 and 420 based on the positioning deviation detected by the alignment detecting device 490, and may also achieve the effect that the positioning deviation converges to the predetermined deviation threshold range. In another modified embodiment, the first drive roll 410 is configured such that the strip of film passing into the first drive roll 410 and the strip of film passing out of the first drive roll 410 form an obtuse angle, which facilitates handling. In yet another alternative embodiment, the roller set 460 may not be provided, depending on the application. In another modified embodiment, the calender roll 474, the peeling roll 480, and the curing device 476 may not be provided, or the positions of the calender roll 474, the peeling roll 480, and the curing device 476 may be modified, as desired by the application.

As shown in fig. 7, in one embodiment, the film handling system 400 may further include a loading assembly 710, the loading assembly 710 configured to transport the film strip to the first drive roll 410. The feeding assembly 710 includes: a discharge roller 711, a film collecting roller 712, a dust adhering device 713 and a feeding tension roller 714.

The discharging roller 711 is used for placing a first composite film strip 550, and the first composite film strip 550 includes a film strip 510 and a first protective film 560 attached to the film strip. The take-up roll 712 is configured to receive the first protective film 560 separated from the first composite film strip 550. The dust adhering device 713 is used for performing dust adhering treatment on the film strip 510 separated from the first protective film strip. The dust adhering device 713 in fig. 7 can perform a double-sided lining process on the film strip 510. The film strip 510 passes through the dust adhering device 713 and the feeding tension roller 714 in sequence. And the feeding tension roller is used for controlling the unreeling tension.

The position of the take-up roll 712 may also be adjusted. Preferably, the take-up roll 712 may be placed before the glue applicator 472 and after the last contact with the first protective film side component of the first composite film strip 550. Such as shown in fig. 5, the take-up roll 712 may be positioned adjacent to a front of the pressure roll 450.

Of course, the feeding assembly 710 may further include other components, such as a deviation-correcting sensor and a deviation-correcting device, where the deviation-correcting sensor is used to detect whether the film strip has a deviation, and if the deviation-correcting sensor detects the deviation, the deviation-correcting device is controlled to correct the deviation, so as to adjust the deviation in the direction perpendicular to the conveying direction of the film strip.

As shown in fig. 8, the film handling system 400 may also include a take-up assembly 810, where the take-up assembly 810 may be configured to receive the film strip 500 from the second drive roll 420. The take-up assembly 810 may include a protective film roll 811, a compounding device 812, and a take-up roll 813. The protective film roller 811 serves to provide a second protective film. The laminating device 812 is configured to laminate the second protective film with the film strip 500 exiting the second drive roll to form a second composite film strip. The material receiving roller 813 is used for receiving the second composite film strip.

The receiving assembly 810 may further include a secondary curing device and a receiving tension roller. The secondary curing device is used for curing the embossed adhesive layer of the film tape again before the film tape 500 is combined with the second protective film. The material receiving tension roller is used for controlling winding tension.

According to another aspect of the second embodiment of the present invention, the present invention also provides a thin film processing method, comprising: the film belt is conveyed forwards by being driven by a first driving roller, wherein the film belt entering the first driving roller comprises a first pattern which is repeatedly arranged along the length direction of the film belt, and the first pattern comprises a first alignment mark; the gluing device forms a glue layer on the film belt from the direction of the first driving roller; the film belt with the formed adhesive layer is conveyed forwards by the driving of a second driving roller, the second driving roller is provided with an embossing structure on the roller surface, the roller surface of the second driving roller is embossed on the adhesive layer of the film belt so as to form second patterns which are repeatedly distributed on the adhesive layer of the film belt, and the second patterns comprise second alignment marks; the alignment detection device detects the alignment deviation of a first alignment mark of a first pattern and a second alignment mark of a second pattern on the film belt transmitted from the second driving roller; the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged within a preset deviation threshold range.

Other technical details regarding the thin film processing method can be found in the above-mentioned description of the thin film processing system 400, and will not be repeated here.

Touch control film

According to another aspect of the present invention, as shown in fig. 3(d) and 4(d), the present invention also provides a touch film including a base layer, a first holding layer located at one side of the base layer, a first conductive layer formed in the first holding layer, a second holding layer located on the first holding layer or at the other side of the base layer, and a second conductive layer formed in the second holding layer. The first and second retaining layers may each be embossed from a glue layer and may therefore also be referred to as glue layers.

Referring to fig. 6(a), the first conductive layer forms a first pattern 518, which includes a visible region 513, a frame region 514, a lead region 515, and a first alignment mark 512 located in the frame region. The first pattern may also include stretch locator indicia 511. The number of the first alignment marks 512 of each first pattern 510 may also be 4, 3, 2 or more, and the positions of the first alignment marks 512 may also be set as required. The shape of the first alignment mark 512 is a cross-shaped ring, and may also be a circular ring, a square ring, a rectangular ring, a diamond ring, or other shapes.

As shown in fig. 6(b), it should be noted that the second conductive layer is formed by filling a conductive material into the second pattern formed by imprinting on the second holding layer, and thus the second pattern formed by imprinting on the second holding layer is identical to the pattern formed by the second conductive layer. Accordingly, the second conductive layer forms a second pattern, and the second pattern 528 includes the visible region 523, the rim region 524, the lead region 525, and the second alignment mark 522 located in the rim region 524. The second alignment marks 522 of the second pattern may be 4, 3, 2 or more, and the shape of the second alignment marks 522 is a dot, but may be other shapes.

As shown in fig. 6(c) and fig. 9, the first alignment mark 512 and the second alignment mark 522 are aligned up and down (or aligned up and down) with each other to ensure that the first conductive layer and the second conductive layer can be aligned up and down as a whole. In one embodiment, the second alignment mark 522 is centered on the first alignment mark 512, and the two are considered to be aligned above and below each other. Of course, if the first alignment mark 512 is only a circle, the second alignment mark 522 may be regarded as the alignment of the two is completed when the two are located in the first alignment mark 512. In addition, other alignment methods are also possible.

The first alignment mark and the second alignment mark are formed by filling metal materials on grooves formed on the corresponding holding layers in an embossing mode.

Third example of a thin film processing scheme

According to one aspect of the present invention, the present invention provides a thin film processing system, which can imprint and form a first pattern and a second pattern on the front and back surfaces of a thin film strip, and realize precise alignment of the two patterns (or precise alignment of a region of the first pattern and a region of the second pattern), and the alignment precision can be ± 0.01 mm.

Fig. 10 is a schematic structural diagram of a thin film processing system 800 according to a third embodiment of the present invention. The main differences from the thin film processing system 400 in fig. 5 are: the thin film processing system 800 of fig. 10 may simultaneously imprint-form the first pattern and the second pattern on both sides of the thin film strip, while the thin film strip 510 received by the thin film processing system 400 of fig. 5 has been imprinted with the first pattern.

As shown in fig. 10, the thin film processing system 800 includes: the gluing device comprises a first gluing device 872a, a first driving roller 820a, a second gluing device 872b, a second driving roller 820b, an alignment detection device 890, a controller 840 and a steering assembly 850.

The first glue applicator 872a is used to form a first layer of glue 921 on a first surface of the film web 910. As shown in fig. 11(a), which illustrates a cross-sectional view of the film strip 910, and fig. 11(b), which illustrates a cross-sectional view of the film strip 910 coated with the first layer of glue 921.

The first driving roller 820a is configured to rotate controllably, the film belt formed with the first glue layer 921 is conveyed forwards by being driven by the first driving roller 820a, the first driving roller 820a is a roller surface provided with an embossing structure, the roller surface of the first driving roller 820a is embossed on the first glue layer 921 of the film belt 910 so as to form a first pattern which is repeatedly arranged on the first glue layer of the film belt, and the first pattern comprises a first alignment mark. The imprinted structures may be micro-scale structures or nano-scale structures. With reference to fig. 11(b) and 5(a), the embossed first layer of adhesive is designated 920, the film strip with the embossed first layer of adhesive is designated 930 at this time, the first pattern may be the first pattern 518 shown in fig. 5(a), and the first registration mark may be 512, which may be referred to above.

The turning assembly 850 may effect a turning of the film web 930, turning a first surface of the film web 930 to a lower surface, which may include a plurality of one or more conductive rollers.

The second glue applicator 872 forms a second glue layer 941 on the second surface of the film strip 930 from the direction of the first drive roll 820 a. As shown in fig. 11(c), which illustrates a cross-sectional view of the film strip coated with the second adhesive layer 941.

Second drive roller 820b, its controlled rotation that is configured, the forward conveying that the film area after forming second glue film 941 is driven via second drive roller 820b, and second drive roller 820b is provided with the impression structure for the roll surface, the roll surface impression of second drive roller 820b is in order to form the second pattern of arranging repeatedly on the second glue film 941 in film area, wherein the second pattern includes second counterpoint sign. The imprinted structures may be micro-scale structures or nano-scale structures. With reference to fig. 11(e) and 6(b), the embossed second layer of adhesive is designated 940, the film strip with the embossed second layer of adhesive is designated 950, the second pattern may be the first pattern 528 shown in fig. 6(b), and the second registration mark may be 522, as described above.

The registration-detecting device 890 detects a registration deviation of the first registration mark of the first pattern and the second registration mark of the second pattern on the film web 950 delivered from the second driving roll 820 b. The controller 840 is configured to regulate and control the rotation speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device 890, so that the alignment deviation converges in a predetermined deviation threshold range. Specifically, the principles and modes of operation of the alignment detection device 890 and the controller 840 are the same as those of the corresponding devices of the thin film processing system 400 in the second embodiment, and are not repeated here.

As shown in fig. 10, the thin film processing system 800 further includes:

a first glue roller 874a disposed behind the first gluing device 872a and disposed adjacent to the first driving roller 820a, wherein the film strip forming the first glue layer is conveyed to the first driving roller 820a through the gap between the first driving roller 820a and the first glue roller 874a via the first glue roller 874 a;

a first peeling roller 880a disposed behind the first driving roller 820a and adjacent to the first driving roller 820a, wherein the film strip passes through a gap between the first driving roller 820a and the first peeling roller 880a via the first driving roller 820a and is conveyed to the first peeling roller 880 a;

the first curing device 876a is used for curing the first glue layer 920 printed by the first driving roller on the film strip;

a second glue roller 874b disposed behind the second glue applicator 872b and disposed adjacent to the second driving roller 820b, wherein the film strip forming the second glue layer passes through the second glue roller 874b and then passes through a gap between the second driving roller 820b and the second glue roller 874b to be conveyed to the second driving roller 820 b;

a second peeling roller 880b disposed behind the second driving roller 820b and adjacent to the second driving roller 820b, wherein the film strip passes through a gap between the second driving roller 820b and the second peeling roller 880b after passing through the second driving roller 820b and is conveyed to the second peeling roller 880 b;

and a second curing device 876b for curing the second adhesive layer imprinted by the second driving roller 820b on the film tape.

Specifically, the operation principle and manner of the sizing devices 872a and 872b, the calender rolls 874a and 874b, the peeling rolls 880a and 880b, and the curing devices 876a and 876b are the same as those of the film processing system 400 in the second embodiment, and are not repeated here.

As shown in fig. 10, the thin film processing system 800 further includes: a stretch detector 830. The stretch detecting device 830 is configured to detect a distance value between two stretch positioning marks on the film strip between the first driving roller and the second driving roller; the controller 840 is further configured to regulate and control the rotation speeds of the first driving roller and the second driving roller based on the distance value detected by the stretching detection device, so that the distance value is converged within a predetermined distance threshold range. Each first pattern is provided with a stretching positioning mark. Specifically, the operation principle and manner of the stretch detecting device 830 and the controller 840 are the same as those of the corresponding device of the film processing system 400 in the second embodiment, and are not repeated here.

In a further embodiment, the thin film processing system 800 further comprises:

a coating device (not shown) for coating the conductive material on the double-sided embossed thin film strip 950, so that the conductive material is filled in the grooves of the first pattern and the second pattern;

the polishing device is used for polishing two surfaces of the coated film belt and removing the conductive material residues outside the groove areas of the first pattern and the second pattern;

and a sintering device for sintering both sides of the polished thin film strip to obtain a thin film strip 990 shown in fig. 11, wherein a first conductive layer 970 is formed in the embossed first glue layer 920 (which may also be referred to as a first holding layer) and a second conductive layer 960 is formed in the embossed second glue layer 940 (which may also be referred to as a second holding layer). Cutting the film strip 990 may result in a plurality of touch film elements.

According to another aspect of the present invention, there is provided a thin film processing method, comprising:

the first gluing device forms a first glue layer on the first surface of the film belt;

the film belt with the first adhesive layer formed is conveyed forwards by a first driving roller in a driven mode, the first driving roller is provided with an embossing structure on a roller surface, the roller surface of the first driving roller is embossed on the first adhesive layer of the film belt so as to form first patterns which are repeatedly arranged on the first adhesive layer of the film belt, and the first patterns comprise first alignment marks;

the second gluing device forms a second glue layer on the second surface of the film belt from the direction of the second driving roller;

the film belt with the second adhesive layer formed is conveyed forwards by a second driving roller in a driven mode, the second driving roller is provided with an embossing structure on the roller surface, the roller surface of the second driving roller is embossed on the second adhesive layer of the film belt so as to form second patterns which are repeatedly arranged on the second adhesive layer of the film belt, and the first patterns comprise second alignment marks;

the alignment detection device detects the alignment deviation of a first alignment mark of a first pattern and a second alignment mark of a second pattern on the film belt transmitted from the second driving roller;

the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged within a preset deviation threshold range.

In a further embodiment, the thin film processing method further comprises: coating a conductive material on the film belt subjected to double-sided imprinting so that the conductive material is filled into the grooves of the first pattern and the second pattern; polishing both sides of the coated film strip, and removing the conductive material residues outside the groove areas of the first pattern and the second pattern; sintering both sides of the polished film strip.

According to another aspect of the present invention, there is provided a touch film unit comprising: the semiconductor device includes a base layer, a first holding layer located at one side of the base layer, a first conductive layer formed in the first holding layer, a second holding layer located at the other side of the base layer or on the first holding layer, and a second conductive layer formed in the second holding layer. The first and second retaining layers may each be embossed from a glue layer.

Specifically, referring to fig. 6, the first conductive layer forms a first pattern 518 including a visible region 513, a bezel region 514, a lead region 515, and a first alignment mark 512 located in the bezel region. The first pattern may also include stretch locator indicia 511. The second conductive layer forms a second pattern, and the second pattern 528 includes a visible region 523, a rim region 524, a lead region 525, and a second alignment mark 522 located in the rim region 524. The first alignment mark 512 and the second alignment mark 522 are aligned up and down (or aligned up and down) with each other to ensure that the first conductive layer and the second conductive layer can be aligned up and down as a whole.

As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, including not only those elements listed, but also other elements not expressly listed.

In this document, the terms front, back, upper and lower are used to define the components in the drawings and the positions of the components relative to each other, and are used for clarity and convenience of the technical solution. It is to be understood that the use of the directional terms should not be taken to limit the scope of the claims.

The features of the embodiments and embodiments described herein above may be combined with each other without conflict.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (13)

1. A thin film processing system, comprising:

a first glue applicator configured to form a first glue layer on a first surface of the film strip;

the film tape is driven by the first driving roller to be conveyed forwards, the first driving roller is provided with an embossing structure on the roller surface, and the roller surface of the first driving roller is embossed on the first adhesive layer of the film tape so as to form first patterns which are repeatedly arranged on the first adhesive layer of the film tape, wherein the first patterns comprise first alignment marks;

a second glue applicator configured to form a second glue layer on a second surface of the film strip from the first drive roll direction;

the second driving roller is configured to rotate controllably, the film belt formed with the second adhesive layer is conveyed forwards by the driving of the second driving roller, the second driving roller is provided with an embossing structure on the roller surface, and the roller surface of the second driving roller is embossed on the second adhesive layer of the film belt so as to form second patterns which are repeatedly arranged on the second adhesive layer of the film belt, wherein the second patterns comprise second alignment marks;

the alignment detection device detects the alignment deviation of a first alignment mark of a first pattern and a second alignment mark of a second pattern on the film belt which is transmitted from the second driving roller;

and the controller is configured to regulate and control the alignment deviation based on the alignment detection device so as to realize alignment.

2. The thin film processing system as claimed in claim 1, further comprising:

a turning assembly disposed between the first drive roll and the second drive roll for turning the film strip,

the controller is configured to regulate and control the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged within a preset deviation threshold range.

3. The thin film processing system of claim 1,

the first glue spreading roller is arranged behind the first glue spreading device and is arranged close to the first driving roller, and the film belt forming the first glue layer passes through the first glue spreading roller and then passes through a gap between the first driving roller and the first glue spreading roller to be conveyed to the first driving roller;

a first stripping roller arranged behind the first driving roller and adjacent to the first driving roller, wherein the film strip passes through a gap between the first driving roller and the first stripping roller after passing through the first driving roller and is conveyed to the first stripping roller;

the first curing device is used for curing the first adhesive layer stamped by the first driving roller on the film belt;

the second glue pressing roller is arranged behind the second gluing device and is arranged close to the second driving roller, and the film belt forming the second glue layer passes through the second glue pressing roller and then passes through a gap between the second driving roller and the second glue pressing roller to be conveyed to the second driving roller;

a second stripping roller arranged behind the second driving roller and close to the second driving roller, wherein the film strip passes through a gap between the second driving roller and the second stripping roller after passing through the second driving roller and is conveyed to the second stripping roller;

and the second curing device is used for curing the second adhesive layer pressed by the second driving roller on the film belt.

4. The thin film processing system of claim 1,

the glue applying device comprises a glue dispensing head, and the glue dispensing head reciprocates to complete glue dispensing; or;

the gluing device comprises an anilox roller, and the anilox roller finishes gluing through rotation; or

The glue applying device comprises one or more groups of glue dispensing heads, each group of glue dispensing head comprises at least one automatic glue dispensing head and at least one manual glue dispensing head, and the automatic glue dispensing heads can slide to perform automatic glue dispensing on the film belts; the manual dispensing head can slide on the film belt for manual dispensing.

5. The thin film processing system of claim 1,

the alignment detection device comprises a photoelectric sensor or an image acquisition device, wherein the photoelectric sensor or the image acquisition device identifies a first alignment mark of the first pattern and a second alignment mark of the second pattern, and measures alignment deviation between the alignment marks according to the first alignment mark and the second alignment mark.

6. The thin film processing system of claim 1,

the alignment detection device continuously detects the alignment deviation of each group of corresponding first patterns and second patterns, when the current alignment deviation detected by the alignment detection device exceeds a preset deviation threshold range, the controller regulates and controls the rotating speed of the first driving roller and the second driving roller, and further regulates the stretching degree of the film belt between the first driving roller and the second driving roller, so that the alignment deviation obtained by subsequent detection is closer to the preset deviation threshold range, and the alignment deviation is converged in the preset deviation threshold range through one or more times of regulation and control.

7. The thin film processing system of claim 6,

the first alignment mark of the first pattern comprises a plurality of first alignment marks, the second alignment mark of the second pattern comprises a plurality of second alignment marks, the plurality of first alignment marks and the plurality of second alignment marks respectively correspond to each other,

the alignment detection device can detect a plurality of alignment deviations of a plurality of corresponding first alignment marks and second marks according to a group of corresponding first patterns and second patterns, and the controller regulates and controls the rotating speed of the first driving roller and the second driving roller, so that each alignment deviation detected according to each group of corresponding first patterns and second patterns is converged within a preset deviation threshold range.

8. The thin film processing system of claim 1, further comprising:

the stretching detection device is configured to detect a distance value between two stretching positioning marks on the film strip between the first driving roller and the second driving roller;

the controller is also configured to regulate and control the rotating speeds of the first driving roller and the second driving roller based on the distance value detected by the stretching detection device, so that the distance value is converged within a preset distance threshold range.

9. The film processing system according to claim 8, wherein each first pattern is provided with a stretch positioning mark, and the stretch detecting device detects a distance value between two stretch positioning marks on two adjacent first patterns on the film strip; or

Each first pattern is provided with a plurality of stretching positioning marks, and the detection device detects the distance value between any two stretching positioning marks on each first pattern on the film strip and/or the distance value between any two stretching positioning marks on adjacent first patterns; or

One or more of the first registration marks on the first pattern are used as stretch location marks.

10. The thin film processing system of claim 8,

when the detected distance value is larger than the preset distance threshold range, the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller so that the speed of the film belt transmitted from the first driving roller is larger than the speed of the film belt transmitted from the second driving roller,

and when the detected distance value is smaller than the preset distance threshold range, the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller, so that the speed of the film belt transmitted from the first driving roller is smaller than the speed of the film belt transmitted from the second driving roller.

11. The thin film processing system of claim 1,

the coating device is used for coating the conductive material on the film belt subjected to double-sided imprinting so that the conductive material is filled into the grooves of the first pattern and the second pattern;

the polishing device is used for polishing two surfaces of the coated film belt and removing the conductive material residues outside the groove areas of the first pattern and the second pattern;

and the sintering device is used for sintering the two surfaces of the polished film belt.

12. A method of processing a thin film, comprising:

the first gluing device forms a first glue layer on the first surface of the film belt;

the film belt with the first adhesive layer formed is conveyed forwards by a first driving roller in a driven mode, the first driving roller is provided with an embossing structure on a roller surface, the roller surface of the first driving roller is embossed on the first adhesive layer of the film belt so as to form first patterns which are repeatedly arranged on the first adhesive layer of the film belt, and the first patterns comprise first alignment marks;

the second gluing device forms a second glue layer on the second surface of the film belt from the direction of the second driving roller;

the film belt with the second adhesive layer formed is conveyed forwards by a second driving roller in a driven mode, the second driving roller is provided with an embossing structure on the roller surface, the roller surface of the second driving roller is embossed on the second adhesive layer of the film belt so as to form second patterns which are repeatedly arranged on the second adhesive layer of the film belt, and the first patterns comprise second alignment marks;

the alignment detection device detects the alignment deviation of a first alignment mark of a first pattern and a second alignment mark of a second pattern on the film belt transmitted from the second driving roller;

the controller regulates and controls to realize the alignment based on the alignment deviation obtained by the alignment detection device.

13. The thin film processing method as claimed in claim 12, further comprising:

coating a conductive material on the film belt subjected to double-sided imprinting so that the conductive material is filled into the grooves of the first pattern and the second pattern;

polishing both sides of the coated film strip, and removing the conductive material residues outside the groove areas of the first pattern and the second pattern;

sintering both sides of the polished film strip,

the controller regulates and controls the rotating speeds of the first driving roller and the second driving roller based on the alignment deviation obtained by the alignment detection device, so that the alignment deviation is converged within a preset deviation threshold range.

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