JP4870836B1 - Narrow frame touch input sheet manufacturing method - Google Patents

Abstract

Provided is a method for manufacturing a narrow frame touch input sheet which is suitable for a capacitive touch sensor having a narrow frame and a transparent conductive film pattern having two layers, and which is also excellent in rust prevention.
A conductive sheet in which a transparent conductive film 3, a light-shielding conductive film 1, and a first resist layer are sequentially laminated on both sides of a transparent base sheet is used, and the first resist layer is exposed and developed simultaneously on both sides. Then, the transparent conductive film and the light-shielding conductive film are simultaneously etched, and after the first resist layer is peeled off, a patterned second resist layer is formed on the exposed light-shielding conductive film by lamination. Then, only the light-shielding conductive film in the central window part and the terminal part is etched to expose the transparent conductive film, and the second resist layer is left as a rust prevention layer without being peeled off.
[Selection] Figure 2

Description

  The present invention relates to a narrow frame touch input sheet suitable for a capacitive touch sensor having a narrow frame and a two-layer transparent conductive film pattern, and a manufacturing method thereof.

  Conventionally, after forming a metal film on each terminal of the lead terminal of the transparent electrode, the transparent electrode pattern in the input panel region and the metal film and the transparent electrode in the lead terminal row are simultaneously etched to form a touch input device. There was Patent Document 1 as a document.

  In the invention of Patent Document 1, as shown in FIG. 6, a transparent electrode made of an ITO film 31 is formed on a polyester film 30, a photoresist film 32 is formed on the transparent electrode, and then on the photoresist film 32. After covering with a mask 33, a metal film 34 made of In film is formed, the mask 33 is removed, the photoresist film 32 is removed with a resist stripping solution, and the metal film 34 is patterned, and then patterned. A second photoresist film 35 is formed on the formed metal film 34 (see FIG. 6E), and the metal film 35 and the ITO film 31 are simultaneously etched away with a ferric chloride aqueous solution or the like. It is an invention of a method of removing the resist film 35 with a resist stripping solution.

Japanese Patent Laid-Open No. 5-108264

  However, according to the method of Patent Document 1, when the second photoresist film 35 is patterned on the patterned metal film 34 shown in FIG. The metal film 34 is thin and the other metal film 34 is thick, and the metal film 34 does not have a desired electrical resistance. Therefore, there is a problem that the metal film 34 cannot be applied to a touch input sheet with a narrow frame in which the metal film 34 must be within a predetermined electric resistance range with a thin line.

  Moreover, in the capacitive touch input sheet, it is necessary to laminate a transparent conductive film pattern normally formed in the X direction and a transparent conductive film pattern formed in the Y direction with an insulating layer interposed therebetween, In the method of Patent Document 1, the metal film and the transparent electrode cannot be formed on the both surfaces in the same position, so two touch input sheets that have been manufactured must be manufactured through a process such as bonding them in position. There was a problem. As a result, there was a problem that the production was reduced, the transmittance of the transparent window portion was lowered, and the thickness became thicker.

  Therefore, an object of the present invention is to solve the above-mentioned problems, and is suitable for a capacitive touch sensor having a narrow frame and a transparent conductive film pattern having two layers, and further has a narrow frame touch excellent in rust prevention. It is to provide a method for manufacturing an input sheet.

According to the first aspect of the present invention, a step of sequentially laminating and forming a transparent conductive film, a light-shielding conductive film, and a first resist layer on both surfaces of the transparent base sheet,
A step of partially exposing the first resist layer on both sides at the same time, and patterning each by developing;
By simultaneously etching and removing the transparent conductive film and the light-shielding conductive film in the portion where the patterned first resist layer is not laminated, the transparent conductive film and the light-shielding property are respectively formed in the central window portions on both sides of the base sheet. Forming an electrode pattern in which the conductive film is laminated without displacement, and forming a thin line drawing circuit pattern in which the transparent conductive film and the light-shielding conductive film are laminated without displacement on the outer frame portions on both sides of the base sheet, respectively. ,
After peeling off the first resist layer, a step of laminating and forming a patterned second resist layer on which the anticorrosive agent is added and exposed on the exposed light-shielding conductive film;
By etching away only the light-shielding conductive film in the portion where the patterned second resist layer is not laminated, the transparent conductive film is exposed in the central window part and the terminal part on both sides of the base sheet. And a step of allowing the second resist layer to remain as a rust preventive layer without peeling off in this state, and a method for producing a narrow frame touch input sheet.

  According to the second aspect of the present invention, the transparent base sheet is composed of a laminate of a plurality of resin sheets, and among these, the resin sheets on the outermost surface and the outermost surface are laminated before the resin sheets are laminated. The transparent conductive film and the light-shielding conductive film are formed in advance, and the first resist layer is formed after the resin sheets are laminated.

  According to the third aspect of the present invention, the transparent base sheet is composed of a laminate of a plurality of resin sheets, and among these, the outermost resin sheet and the outermost resin sheet are laminated before the resin sheets are laminated. The method for producing a narrow frame touch input sheet according to the first aspect, wherein the transparent conductive film is previously formed, and the light-shielding conductive film and the first resist layer are formed after the resin sheets are laminated.

  According to the fourth aspect of the present invention, the anticorrosive agent added to the second resist layer is any one of imidazole, triazole, benzotriazole, benzimidazole, benzthiazole, and pyrazole. A method for manufacturing a narrow-narrow frame touch input sheet according to any of the three aspects is provided.

  The method for manufacturing a narrow frame touch input sheet of the present invention includes a step of sequentially laminating a transparent conductive film, a light-shielding conductive film, and a first resist layer on both sides of a transparent base sheet, and the first resist layer on both sides simultaneously. A step of patterning by partially exposing and developing, and simultaneously removing the transparent conductive film and the light-shielding conductive film in a portion where the patterned first resist layer is not laminated To form electrode patterns in which the transparent conductive film and the light-shielding conductive film are laminated without misalignment in the central window portions on both sides of the base sheet, and the transparent conductive film and the light-shielding properties on the outer frame portions on both sides of the base sheet, respectively. A step of forming a fine wire routing circuit pattern in which the conductive film is laminated without misalignment; and after the first resist layer is peeled off, a rust inhibitor is added to the exposed light-shielding conductive film; A step of laminating a patterned second resist layer, and by etching and removing only the light-shielding conductive film in a portion where the patterned second resist layer is not laminated, A step of exposing the transparent conductive film in each of the window portion and the terminal portion and leaving the second resist layer as a rust-preventing layer without peeling off in this state. Therefore, since an elaborate and fine thin line drawing circuit pattern can be formed, there is an effect that a touch input sheet having a very narrow frame can be manufactured.

  In addition, since the light-shielding conductive film is formed under the first resist layer, when the first resist layer is patterned by a method such as exposure on both sides simultaneously, the light beam of the exposure is applied to the opposite first resist layer. Since it has a high effect of preventing reaching, there is an effect that a narrow frame touch input sheet in which the circuit pattern and the thin line drawing circuit pattern are formed on both surfaces of the base sheet can be manufactured with high productivity and high quality.

  In addition, since a rust inhibitor is added to the second resist layer, there is an effect that it is very excellent in rust prevention. In more detail, if the second resist layer coated on the thin wire drawing circuit pattern is inferior in rust resistance, corrosive liquids such as sweat and salt water from the outside after the product has been invaded. Or, under an environmental test such as high temperature and high humidity, the circuit becomes more corroded and the electrical characteristics deteriorate. In contrast, when a rust inhibitor is added to the second resist layer as in the present invention, even if corrosive liquid enters from the outside after the product is completed, or an environmental test such as high temperature and high humidity. Even underneath, corrosion does not progress in the routing circuit, and electrical characteristics can be maintained. Therefore, the present invention can be sufficiently applied to a use in which the drawing circuit is a thin line and needs to maintain a low resistance over a long period of time, like a double-sided transparent conductive film sheet applied to a capacitive touch sensor or the like.

  Further, since the second resist layer also serves as a rust prevention layer, a process for forming the rust prevention layer separately from the second resist layer is unnecessary, and the cost is low because only a small number of members are required. Further, since the rust preventive layer is not formed separately from the second resist layer, the positional accuracy of the rust preventive region with respect to the thin line drawing circuit pattern is improved.

It is a figure explaining an electrode pattern and a thin line drawing circuit pattern about one Example of the narrow frame touch input sheet which concerns on this invention. It is a schematic cross section showing an example of a narrow frame touch input sheet in which an electrode pattern and a thin line drawing circuit pattern are formed on both surfaces of a transparent base sheet made of a single resin sheet. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. FIG. 5 is a schematic cross-sectional view showing an example of a narrow frame touch input sheet in which an electrode pattern and a thin line drawing circuit pattern are formed on the outermost surface and the outermost surface of a transparent base sheet made of a laminate of two resin sheets. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a schematic cross section which shows the process of manufacturing the narrow frame touch input sheet | seat of FIG. It is a figure for demonstrating the electrode formation process of the touch input device of patent document 1. FIG. It is a top view explaining an example of the shape and arrangement | positioning aspect of the electrode pattern formed in the center window part of a narrow frame touch input sheet.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

<First embodiment>
Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a view for explaining an electrode pattern and a thin line drawing circuit pattern for an embodiment of a narrow frame touch input sheet according to the present invention. FIG. 2 is a schematic cross-sectional view showing an example of a narrow frame touch input sheet in which an electrode pattern and a fine line routing circuit pattern are formed on both surfaces of a transparent base sheet made of a single resin sheet (position of line AA shown in FIG. 1) 3 and FIG. 3 (a) to FIG. 3 (f) are schematic cross-sectional views showing the manufacturing process. In the figure, 1 is a light-shielding conductive film layer, 3 is a transparent conductive film, 5 is a narrow frame touch input sheet, 7 is a resin sheet, 9 is an electrode pattern, 10 is a thin line drawing circuit pattern, 12 is a mask, and 14 is an exposure beam. , 16 is a first resist layer, 18 is a second resist layer (also used as a rust prevention layer), 20 is a capacitive touch sensor, 22 is an outer frame portion of the narrow frame touch input sheet 5, and 24 is a narrow frame touch input sheet. Reference numeral 5 denotes a central window portion and 28 denotes an external circuit.

  In the narrow frame touch input sheet 5 obtained by the present invention, the electrode pattern 9 made of only the transparent conductive film 3 is formed on the central window portions 24 on both sides of the base sheet, and the transparent conductive film 3 and the light-shielding conductive film are formed on the outer frame portion 22. 1 is a narrow frame touch input sheet on which thin line drawing circuit patterns 10 are sequentially laminated (see FIG. 1), and the transparent conductive film 3 and the light-shielding conductive film 1 of the thin line drawing circuit pattern 10 are the same pattern. It is characterized by being laminated without misalignment. The transparent base sheet on which the electrode pattern 9 and the thin line drawing circuit pattern 10 are formed can be composed of a single resin sheet 7 (see FIG. 2).

  The manufacturing method of the narrow frame touch input sheet 5 in which the circuit pattern of the transparent conductive film 3 and the thin line drawing circuit pattern 10 are formed on both sides is as follows. First, the front and back sides of a transparent base sheet made of a single resin sheet 7 are respectively provided. Then, the transparent conductive film 3, the light-shielding conductive film 1, and the first resist layer 16 were sequentially formed over the entire surface to obtain a conductive sheet (see FIG. 3A), and then a mask 12 having a desired pattern was placed on each of the front and back sides. The first resist layer 16 is patterned by exposure (see FIG. 3B) and development. At this time, since the light-shielding conductive film 1 blocks the exposure light beam 14 on the opposite side, even if it is simultaneously exposed with a different mask pattern, the pattern of the first resist layer 16 on the opposite side is not affected. Therefore, since both sides can be exposed simultaneously, the front and back of the first resist layer 16 can be easily aligned, and both sides can be patterned in a single process, and productivity is improved. Note that the position of the mask 12 shown in FIG. 3B shows the case where the first resist layer 16 is a negative type (when exposed, the solubility in the developing solution decreases and the exposed portion remains after development). ing. In the case of the positive type (when exposed, the solubility in the developer increases and the exposed portion is removed), the portion shielded from light by the mask is reversed.

  In addition, the well-known mask alignment method of a double-sided exposure apparatus can be used for alignment of a front mask and a back mask. For example, a mask alignment mark is formed on each of the front mask and the back mask, and an optical reading sensor such as a camera reads the overlapping state of the pair of mask alignment marks, thereby relative to the front mask and the back mask. Get location information. Then, based on the obtained position information, the mask position adjusting mechanism relatively moves the front mask and the back mask so that the pair of mask alignment marks overlap with each other. For example, a method of aligning the back mask.

  Next, the transparent conductive film 3 and the light-shielding conductive film 1 are simultaneously etched with an etchant such as ferric chloride, and the portion of the transparent conductive film 3 and the light-shielding conductive film where the patterned first resist layer 16 is not stacked. By removing the film 1, an electrode pattern 9 in which the transparent conductive film 3 and the light-shielding conductive film 1 are laminated without misalignment is formed in the central window portions on both sides of the base sheet, and the outer frame portions on both sides of the base sheet. Then, a thin line drawing circuit pattern 10 in which the transparent conductive film 3 and the light-shielding conductive film 1 are laminated without misalignment is formed (see FIG. 3C).

  Next, the first resist layer 16 is stripped with a resist stripping solution to expose the light-shielding conductive film 1, and then the second resist layer 18 to which a rust inhibitor is added on the exposed light-shielding conductive film 1 is formed. After the entire surface is formed (see FIG. 3D), the mask 12 is placed, exposed (see FIG. 3E) and developed to pattern the second resist layer 18 (see FIG. 3F). Note that the position of the mask 12 shown in FIG. 3E shows the case where the first resist layer 16 is a negative type (when exposed, the solubility with respect to the developer is lowered and the exposed portion remains after development). ing.

  Next, etching is performed with a special etching solution such as acidified hydrogen peroxide, and only the light-shielding conductive film 1 where the patterned second resist layer 18 is not laminated is removed, whereby the center of both sides of the base sheet is obtained. The transparent conductive film 3 is exposed at each of the window portion 24 and the terminal portion 25 in the outer frame portion 22, and the second resist layer 18 is left as a rust-preventing layer without peeling off (see FIG. 2). Since the second resist layer 18 functions as a rust-preventing layer, even if corrosive liquid enters from the outside after completion of the product, or corrosion occurs in the routing circuit even under environmental tests such as high temperature and high humidity. The electrical characteristics can be maintained. In FIG. 1, the thin line drawing circuit pattern 10 formed on the surface of the base sheet (resin sheet 7) is drawn with the laminated portion of the light-shielding conductive film 1 in black and the exposed portion of the transparent conductive film 3 in white. Both ends of the black portion coincide with a boundary 24a with the central window portion 24 and a boundary 25a with the terminal portion 25.

  If the transparent conductive film 3 is an amorphous material, it is preferably crystallized by a method such as heat treatment before the etching. This is because the etching resistance is improved by crystallization, and only the light-shielding metal film 1 can be easily etched selectively.

  If the end portions of the thin line drawing circuit pattern 10 formed on both surfaces of the narrow frame touch input sheet 5 obtained by the above method are connected to the external circuit 28 on which the IC chip is mounted, respectively, at the terminal portion 25, the base sheet The capacitive touch sensor 20 in which the transparent conductive film 3 is formed on both sides with the electrode 7 interposed therebetween is manufactured.

  Here, the electrode pattern 9 formed on the central window portion 24 of the capacitive touch sensor 20 will be supplementarily described. The electrode pattern 9 has different patterns on the front and back sides. For example, as shown in FIG. 7, on the back surface of the base sheet (resin sheet 7), a rhombus electrode 46 having a rhombus shape in plan view and a plurality of rhombus electrodes 46 are arranged in the vertical direction (Y direction) in the figure. And a connection wiring 469 penetrating therethrough. The plurality of rhombus electrodes 46 and the connection wiring 469 are electrically connected to each other. Further, such a connection wiring 469 and a plurality of rhombus electrodes 46 penetrating therethrough are taken as a set, and the set is repeatedly arranged in the horizontal direction (X direction) in the drawing. On the other hand, on the surface of the base sheet (resin sheet 7), a plurality of rhombus electrodes 47 and connection wirings 479 penetrating them are provided in the same manner. However, in this case, the extending direction of the connection wiring 479 is different from that of the connection wiring 469 in the horizontal direction (X direction) in the drawing. Along with this, the direction in which a set of the connection wiring 479 and the plurality of rhombus electrodes 47 penetrating the connection wiring 479 is repeatedly arranged is the vertical direction (Y direction) in the drawing. As is clear from FIG. 7, the rhombus electrode 46 is disposed so as to fill the gaps between the plurality of connection wirings 479, while the rhombus electrode 47 is disposed so as to fill the gaps between the plurality of connection wirings 469. Is done. Further, in FIG. 7, the positional relationship between the diamond electrode 46 and the diamond electrode 47 is complementary. That is, the plurality of rhombus electrodes 47 are arranged so as to fill in the rhombus-shaped gaps that occur when the rhombus electrodes 46 are arranged in a matrix. As described above, in the present invention, since the light-shielding conductive film 1 blocks the exposure light beam 14 on the opposite surface, even if it is exposed at the same time, this does not affect the pattern of the first resist layer 16 on the opposite side. It is possible to form circuit patterns having different patterns on the front and back surfaces.

  As described above, the X direction electrode and the Y direction electrode are arranged so as to form a lattice in plan view, so that if a user's finger or the like touches any position on the lattice (for example, a dotted circle FR) ), A capacitor is formed between the finger and the X-direction electrode touched by the finger, and a capacitor is formed between the finger and the Y-direction electrode touched by the finger. By forming this capacitor, the capacitance of the X direction electrode and the Y direction electrode increases. The position detector of the external circuit detects the amount of change in capacitance that occurs in such a case, or even the X-direction electrode and Y-direction electrode having the maximum capacitance, and touches anywhere in the central window 24. Can be acquired as a set of an X coordinate value and a Y coordinate value as a specific value.

  Next, each layer forming the narrow frame touch input sheet 5 will be described in detail.

  First, the base sheet is composed of a transparent resin sheet 7 having a thickness of about 30 to 2000 μm, and the material is polyester resin, polystyrene resin, olefin resin, polybutylene terephthalate resin, polycarbonate resin, acrylic resin, or the like. The plastic film etc. are mentioned. In addition, in this invention, it does not prevent using a glass material as a base sheet.

  By the way, when the base sheet of the conductive sheet is a plastic film, there is a problem of elongation of the film. Therefore, the patterning of the first resist layer 16 on both sides of the conductive sheet is suitable by double-sided simultaneous exposure. This is because, when the patterning of the first resist layer 16 is performed by exposing one side at a time, the patterning on one side is finished, and when the base sheet is stretched when the conductive sheet is replaced by replacing the front and back of the conductive sheet, This is because the circuit pattern and the circuit pattern on the back surface are displaced. In the case of the example shown in FIG. 7, the arrangement relationship between the rhombus electrode 46 and the rhombus electrode 47 is complementary, and therefore if the circuit pattern on the front surface and the circuit pattern on the back surface are displaced, the capacitive touch sensor 20. Will not function correctly.

  Examples of the light-shielding conductive film 1 include a single metal film having high conductivity and good light-shielding property, and a layer made of an alloy or a compound thereof, such as a vacuum deposition method, a sputtering method, an ion plating method, and a plating method. It is good to form by. It is also necessary that an etchant exists that is not etched by the transparent conductive film but is etched by the light-shielding conductive film 1 itself. Examples of the preferable metal include aluminum, nickel, copper, silver, and tin. In particular, a metal film made of copper foil with a thickness of 20 to 1000 nm is excellent in conductivity and light shielding properties, and the transparent conductive film can be easily etched with hydrogen peroxide in an acidic atmosphere that is not etched. It is very preferable because it has ease of use. More preferably, the thickness is 30 nm or more. More preferably, it is good to set it as 100-500 nm. This is because a highly conductive light-shielding metal film layer 1 can be obtained by setting the thickness to 100 nm or more, and a light-shielding metal film layer 1 that is easy to handle and excellent in workability can be obtained by setting the thickness to 500 nm or less.

  The transparent conductive film 3 includes a layer made of a metal oxide such as indium tin oxide or zinc oxide, and may be formed by a vacuum evaporation method, a sputtering method, an ion plating method, a plating method, or the like. The film is formed with a thickness of about several tens to several hundreds of nanometers. A solution such as ferric chloride is easily etched together with the light-shielding conductive film 1, but the light-shielding conductive film 1 such as hydrogen peroxide solution in an acidic atmosphere is used. It must be not easily etched with an etchant. And it is preferable to show a light transmittance of 80% or more and a surface resistance value of several mΩ to several hundred Ω. The transparent conductive film 3 may be a conductive polymer film such as thiophene, or a conductive fiber film including metal nanowires or carbon nanotubes. In that case, the transparent conductive film 3 may be formed by various printing methods or painting.

  The first resist layer 16 is made of an acrylic photoresist material having a thickness of 10 to 20 μm, which can be exposed with a high pressure mercury lamp, an ultrahigh pressure mercury lamp, a laser beam or a metal halide lamp and developed with an alkaline solution. This is because the thin line drawing circuit pattern 10 having a narrow line width can be formed with certainty by exposure and development with a photoresist material, and the narrow frame touch input sheet 5 can be manufactured. The first resist layer 16 may be formed by a general printing method such as gravure, screen, or offset, as well as various coater methods, coating and dipping methods, and various methods such as a dry film resist method, followed by exposure. -It is good to develop and pattern, but the dry film resist method is more preferable.

  The dry film resist (DFR) used in the dry film resist method is a film in which a photosensitive layer that becomes the first resist layer 16 is sandwiched between a base film and a cover film. The above printing method, coating method, painting method, etc. have problems such as only one side coating and poor efficiency, whereas the dry film resist method bonds the photosensitive layer with a heating roll after peeling the cover film. This method is mainstream because it is highly productive and can meet various requirements. The exposure is usually performed by placing a mask on the base film (not shown), and development is performed after the base film is peeled off. As the base film of the dry film resist, a film made of polyethylene terephthalate or the like can be used. Moreover, what consists of polyethylene etc. can be used as a cover film of a dry film resist.

  The second resist layer 18 is preferably composed of the aforementioned photoresist material to which a rust inhibitor has been added. As the rust preventive agent, a material that is already used as a rust preventive agent is used. As specific examples, for example, imidazole, triazole, benzotriazole, benzimidazole, benzthiazole, pyrazole and the like may be used. In addition, monocyclic or polycyclic azoles such as halogen, alkyl, and phenyl-substituted products, aromatic amines such as aniline, aliphatic amines such as alkylamine, salts thereof, and the like. There is no need to be limited to the materials described herein. The second resist layer 18 may be formed by a general printing method such as gravure, screen, or offset, as well as various coater methods, coating and dipping methods, and various methods such as a dry film resist method, followed by exposure. -It is good to develop and pattern, but the dry film resist method is more preferable. In addition, since a precise pattern is not formed, the pattern may be formed suddenly by a printing method without using a photo process.

  Further, a pattern layer for concealing the thin line drawing circuit pattern 10 and improving the appearance design may be provided on the second resist layer 18. For the pattern layer, it is preferable to use colored ink containing a resin such as polyvinyl, polyamide, polyacrylic, polyurethane, or alkyd as a binder and a pigment or dye of an appropriate color as a colorant. In addition, metal particles such as aluminum, titanium, bronze, and pearl pigments in which mica is coated with titanium oxide can also be used as the colorant. As a method for forming the pattern layer, there are general printing methods such as gravure, screen, and offset, various coating methods, and methods such as painting.

<Second embodiment>
The embodiment of the method for manufacturing the narrow frame touch input sheet in which the circuit pattern and the thin line drawing circuit pattern are formed on the front and back surfaces of the transparent base sheet made of the single resin sheet 7 has been described above. Is not limited to this.

  For example, the circuit pattern of the transparent conductive film 3 and the thin line drawing circuit pattern 10 can be formed on the outermost surface and the outermost surface of a transparent base sheet in which a plurality of resin sheets 7 and 7 are laminated (see FIG. 4). . In order to obtain such a narrow frame touch input sheet, first, the transparent conductive film 3 and the light-shielding conductive film 1 are sequentially laminated in advance on each side using two thin resin sheets 7 and 7, After laminating them so that the resin sheets 7 and 7 face each other (see FIG. 5A), the first resist layer 16 is formed on both surfaces (see FIG. 5B). Alternatively, only the transparent conductive film 3 is formed in advance before the resin sheets 7 and 7 are laminated, and these are laminated so that the resin sheets 7 and 7 face each other, and then the light-shielding conductive film 1 and the first resist layer 16 are formed on both surfaces. Are sequentially stacked. Moreover, after laminating the resin sheets 7, 7, the transparent conductive film 3, the light-shielding conductive film 1, and the first resist layer 16 may be sequentially laminated on both surfaces. In addition, as a lamination | stacking means of the base sheet 7, a thermal lamination, the dry lamination via an adhesive bond layer, etc. are mentioned. When the resin sheet 7 is laminated with the adhesive layer, the thickness of the entire laminate can be adjusted by using an adhesive layer having a core material. Moreover, the thickness adjustment of the whole laminated body can also be performed by interposing another resin sheet between the resin sheets 7 and 7 of the outermost surface and the outermost surface.

  The following steps are the same as in the second embodiment. That is, a mask 12 having a desired pattern is placed on the outermost surface and the outermost surface of a transparent substrate sheet made of a laminate, and the first resist layer 16 is patterned by exposure (see FIG. 5C) and development.

  Next, the transparent conductive film 3 and the light-shielding conductive film 1 are simultaneously etched with an etchant such as ferric chloride, and the portion of the transparent conductive film 3 and the light-shielding conductive film where the patterned first resist layer 16 is not stacked. By removing the film 1, an electrode pattern 9 in which the transparent conductive film 3 and the light-shielding conductive film 1 are laminated without misalignment is formed in the central window portions on both sides of the base sheet, and the outer frame portions on both sides of the base sheet. Then, a thin line drawing circuit pattern 10 in which the transparent conductive film 3 and the light-shielding conductive film 1 are laminated without misalignment is formed (see FIG. 5D).

  Next, the first resist layer 16 is stripped with a resist stripping solution to expose the light-shielding conductive film 1, and then the second resist layer 18 to which a rust inhibitor is added on the exposed light-shielding conductive film 1 is formed. After the entire surface is formed (see FIG. 5E), the mask 12 is placed, exposed (see FIG. 5F) and developed to pattern the second resist layer 18 (see FIG. 5G).

  Next, etching is performed with a special etching solution such as acidified hydrogen peroxide, and only the light-shielding conductive film 1 where the patterned second resist layer 18 is not laminated is removed, whereby the center of both sides of the base sheet is obtained. The transparent conductive film 3 is exposed at each of the window portion 24 and the terminal portion 25 in the outer frame portion 22, and the second resist layer 18 is left as a rust-proof layer without being peeled off. A narrow frame touch input sheet using a laminate of a plurality of resin sheets as a base sheet is obtained.

Example 1
A sheet of colorless polyester film with a thickness of 400 μm is used as a base sheet, and a transparent conductive film is formed on both front and back surfaces with a thickness of 200 nm by a sputtering method made of indium tin oxide, and a copper film is formed thereon as a light-shielding conductive film. Using a dry film resist having a negative acrylic photosensitive layer formed with a thickness of 500 nm by sputtering and developable with 1% caustic soda solution, a first resist layer having a thickness of 10 nm is formed on the entire surface. A mask having an X-direction electrode pattern was placed on the back, and a mask having a Y-direction electrode pattern was placed on the back side, and both the front and back surfaces were exposed simultaneously by a metal halide lamp, and developed by immersion in 1% caustic soda solution. .

  Next, the portion of the indium tin oxide film and the copper film where the patterned first resist layer is not laminated is simultaneously etched away with a ferric chloride etchant. An X-direction electrode pattern is formed with the Y-direction electrode pattern exposed on the back side, and a thin line drawing pattern with an average line width of 20 μm is formed on both the front and back surfaces of the outer frame surrounding the central window. It was.

  Next, after peeling off the first resist layer, a dry film resist having a negative type acrylic photosensitive layer that can be developed with 1% caustic soda solution and benzoimidar is added as a rust preventive agent is used, and the thickness is 10 nm. A second resist layer was formed on the entire surface, a mask was placed on the outer frame portion excluding the front and back terminal portions, and both front and back surfaces were exposed simultaneously by a metal halide lamp, and immersed in a 1% caustic soda solution for development.

  Next, the exposed copper film in the central window that was exposed when immersed in hydrogen peroxide in an acidic atmosphere was etched away, leaving only the indium tin oxide film formed therebelow. Thereafter, the second resist layer was left as a rust preventive layer without peeling off.

Example 2
A point of using a laminate of two colorless polyester films with a thickness of 200 μm as the basic sheet. Each polyester film has a transparent conductive film and a light-shielding conductive film formed on one side in advance before lamination. A narrow frame touch input sheet was obtained by the same method as in Example 1 except that the first resist layer was formed on both sides later.

Example 3
A point of using a laminate of two 200μm thick colorless polyester films as the basic sheet. Each polyester film is preliminarily formed with a transparent conductive film on one side. A narrow frame touch input sheet was obtained by the same method as in Example 1 except that the conductive film and the first resist layer were formed.

Example 4
A narrow frame touch input sheet was obtained in the same manner as in Example 1 except that the rust inhibitor added to the second resist layer was changed to benzoimidal of Example 1 and changed to benzotriazole.

  According to the methods of Examples 1 to 4, only the indium tin oxide film having the X-direction electrode pattern and the Y-direction electrode pattern is formed on both sides of the base sheet in the central window portion, and indium is formed on each outer frame portion. A narrow line touch circuit in which a copper wire is formed on the tin oxide film except for the terminal portion is formed, and the thin wire lead circuit is covered with a second resist layer containing a rust preventive agent except for the terminal portion. An input sheet was obtained. When the end portion of the thin line drawing circuit pattern formed on the narrow frame touch input sheet is connected to an external circuit on which an IC chip is mounted to evaluate whether to operate as a capacitive touch sensor, Examples 1-4 In either case, good results can be obtained, and even if corrosive liquid enters from the outside after completion of the product, or under the environmental test such as high temperature and high humidity, the circuit is not corroded. Electrical characteristics were maintained.

  The present invention is an invention of a method for manufacturing a narrow frame touch input sheet that can be applied to an input device such as a mobile phone, a PDA, a small PC, or the like provided with a video screen such as a liquid crystal panel.

DESCRIPTION OF SYMBOLS 1 Light-shielding electrically conductive film 3 Transparent electrically conductive film 5 Narrow frame touch input sheet 7 Resin sheet 9 Electrode pattern 10 Thin line drawing circuit pattern 12 Mask 14 Exposure light 16 First resist layer 18 Second resist layer 20 Capacitive touch sensor 22 Narrow Outer frame portion of the frame touch input sheet 5 24 Central window portion of the narrow frame touch input sheet 5 25 Terminal portions of the narrow frame touch input sheet 5 46, 47 Diamond electrode 469.479 Connection wiring

Claims (4)

A step of sequentially laminating and forming a transparent conductive film, a light-shielding conductive film, and a first resist layer on both surfaces of the transparent base sheet;
A step of partially exposing the first resist layer on both sides at the same time, and patterning each by developing;
By simultaneously etching and removing the transparent conductive film and the light-shielding conductive film in the portion where the patterned first resist layer is not laminated, the transparent conductive film and the light-shielding property are respectively formed in the central window portions on both sides of the base sheet. Forming an electrode pattern in which the conductive film is laminated without displacement, and forming a thin line drawing circuit pattern in which the transparent conductive film and the light-shielding conductive film are laminated without displacement on the outer frame portions on both sides of the base sheet, respectively. ,
After peeling off the first resist layer, a step of laminating and forming a patterned second resist layer on which the anticorrosive agent is added and exposed on the exposed light-shielding conductive film;
By etching away only the light-shielding conductive film in the portion where the patterned second resist layer is not laminated, the transparent conductive film is exposed in the central window part and the terminal part on both sides of the base sheet. And a step of leaving the second resist layer as a rust-preventing layer without peeling off the second resist layer in that state, and a method for producing a narrow frame touch input sheet.   The transparent base sheet is composed of a laminate of a plurality of resin sheets, and among these, the transparent conductive film and the light-shielding conductive film are preliminarily formed on the outermost and rearmost resin sheets before the resin sheets are laminated. The method for manufacturing a narrow frame touch input sheet according to claim 1, wherein the first resist layer is formed after the resin sheets are laminated.   The transparent base sheet is composed of a laminate of a plurality of resin sheets, among which the transparent conductive film is formed in advance on the outermost and rearmost resin sheets before the resin sheets are laminated, The method for manufacturing a narrow frame touch input sheet according to claim 1, wherein the light-shielding conductive film and the first resist layer are formed after the resin sheets are laminated. The narrow frame touch input according to any one of claims 1 to 3, wherein the rust inhibitor added to the second resist layer is any one of imidazole, triazole, benzotriazole, benzimidazole, benzthiazole, and pyrazole. Sheet manufacturing method.

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