JP2014026584A - Transparent wiring sheet and manufacturing method of the same, and input member for touch panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transparent wiring sheet capable of easily increasing a yield of an electrode sheet, easily reducing, when processed to an electrode sheet, deviation in dimension from an electrode sheet forming a pair, and securing sufficiently high coordinate detection accuracy when used as an input member for a touch panel.SOLUTION: A transparent wiring sheet 1 of the present invention has a first electrode 21a formed to be perpendicular to a direction to apply a fiber dispersion liquid including conductive ultrafine fibers, and to have an aspect ratio of more than 1.

Description

  The present invention relates to a transparent wiring sheet used as an input member in a projected capacitive touch panel and a method for manufacturing the same. The present invention also relates to an input member of a projected capacitive touch panel.

In recent years, touch panels have been widely used in mobile phones, game machines, office office equipment, and the like. The touch panel usually includes an input member for coordinate detection on the front surface of an image display device such as a liquid crystal display.
As the input member, for example, a member having a pair of electrode sheets on which high aspect ratio electrodes are formed and the electrodes are insulated from each other is used (Patent Document 1). As the electrode sheet, a rectangular sheet in which a transparent conductive layer is provided on one side of a transparent insulating substrate and an insulating pattern is formed on the transparent conductive layer is used. As a conductive material constituting the transparent conductive layer, tin-doped indium oxide is widely used. In recent years, conductive ultrafine fibers such as silver nanowires are sometimes used (Patent Documents 2 and 3).
When conductive ultrafine fibers are used, the conductive ultrafine fibers can be applied to the surface of a transparent insulating substrate such as a glass plate or a long polyester film by applying a large shear stress to the coating liquid such as a slot die or a micro gravure coater. A conductive sheet is formed by applying a coating liquid containing a transparent substrate to form a transparent conductive layer, and an insulating pattern is formed on the transparent conductive layer of the conductive sheet to form an electrode sheet. After producing a transparent wiring sheet including a region, this is punched out to obtain an electrode sheet.

Japanese Patent Laid-Open No. 11-170072 JP 2011-167848 A JP 2012-032864 A

However, in the conventional transparent wiring sheet, the yield of the electrode sheet may be low, and when the input member of the touch panel is used, there may be a large dimensional deviation between the paired electrode sheets. May not be sufficiently secured.
Therefore, the present invention can easily increase the yield of the electrode sheet, can easily reduce the dimensional deviation from the paired electrode sheet, and has sufficiently high coordinate detection accuracy when used as an input member of a touch panel. It aims at providing the transparent wiring sheet which can be ensured, and its manufacturing method. Moreover, it aims at providing the input member which can detect a coordinate correctly.

In the conductive sheet obtained by applying the dispersion of conductive ultrafine fibers, the electrical resistance in the application direction of the dispersion of conductive ultrafine fibers (longitudinal direction of the conductive sheet) tends to be low. It was thought that it was necessary to match the longitudinal direction of the electrode with the direction of application of the dispersion of conductive ultrafine fibers. However, the inventors have realized that it is not necessarily correct for the following reasons.
One and the other of the pair of electrode sheets are often produced from separate conductive sheets having the same width or are produced from the same conductive sheet. However, in either case, when the longitudinal direction of the electrode is aligned with the direction of application of the conductive fine fiber dispersion, the remaining portion after punching, that is, the portion to be discarded tends to increase, and the yield tends to decrease. It was. Furthermore, the transparent insulating base material tends to shrink in the longitudinal direction, and when the transparent insulating base material shrinks in the longitudinal direction, the dimensions of the pair of electrode sheets may not match. If the dimensions of the pair of electrode sheets do not match, the coordinates may not be detected correctly. Therefore, it is not always good to match the longitudinal direction of the electrode with the coating direction of the dispersion liquid of the conductive ultrafine fibers.
Therefore, the present inventors have invented the following transparent wiring sheet, a manufacturing method thereof, and an input member for a touch panel.

[1] A transparent insulating substrate and a transparent conductive layer provided on one surface side of the transparent insulating substrate, an input area disposed in the center in plan view, and disposed outside the input area A transparent wiring layer, wherein the transparent conductive layer in the input area is insulated in a pattern and a plurality of first electrodes for coordinate detection are formed. After forming a two-dimensional network of conductive ultrafine fibers by applying a fiber dispersion containing conductive ultrafine fibers along one direction α, a transparent substrate paint containing a transparent substrate is formed on the two-dimensional network. A transparent wiring sheet, which is a layer formed by coating, wherein the first electrode is formed so as to be perpendicular to the direction α and to have an aspect ratio of more than 1.
[2] The transparent electrode according to [1], wherein the first electrode has a wide portion and a narrow portion narrower than the wide portion alternately formed along a longitudinal direction thereof. Wiring sheet.
[3] The portion of the transparent conductive layer insulated in the pattern is irradiated with laser light in a pattern on the transparent conductive layer, and the conductive microfibers are evaporated and removed without melting the transparent substrate. The transparent wiring sheet according to [1] or [2], wherein
[4] The transparent wiring sheet according to any one of [1] to [3], wherein the transparent insulating substrate is a long film, and the longitudinal direction of the film is the direction α.

[5] After forming a two-dimensional network of conductive ultrafine fibers by applying a fiber dispersion containing conductive ultrafine fibers along one direction α to one surface side of the transparent insulating substrate, the two-dimensional network A transparent conductive layer forming step of forming a transparent conductive layer by applying a transparent substrate coating material including a transparent substrate, and insulating the transparent conductive layer in a pattern so that a plurality of first layers having an aspect ratio of more than 1 are formed. And a first electrode forming step of forming one electrode so that its longitudinal direction is perpendicular to the direction α. A method for producing a transparent wiring sheet, comprising:
[6] In the first electrode formation step, the first electrode is formed so that wide portions and narrow portions narrower than the wide portions alternate along the longitudinal direction. 5] The manufacturing method of the transparent wiring sheet as described in 5].
[7] Pattern insulation of the transparent conductive layer in the first electrode forming step irradiates the transparent conductive layer with a laser beam in a pattern to evaporate and remove the conductive ultrafine fibers without melting the transparent substrate. The method for producing a transparent wiring sheet according to [5] or [6], wherein:
[8] The production of the transparent wiring sheet according to any one of [5] to [7], wherein a long film is used as the transparent insulating substrate, and the longitudinal direction of the film is the direction α. Method.
[9] A portion of the transparent conductive layer where the first electrode is not formed is insulated in a pattern, and a plurality of second electrodes having an aspect ratio of more than 1 are arranged so that their longitudinal directions are parallel to the direction α. And a second electrode forming step of forming the first electrode so as to be arranged in parallel in an insulated state, and alternately arranging the first electrode and the second electrode along the longitudinal direction of the transparent insulating substrate. [8] The method for producing a transparent wiring sheet according to [8].

[10] A first electrode sheet in which electrodes for coordinate detection are provided along the direction X, and a second electrode sheet in which electrodes for coordinate detection are provided along the direction Y perpendicular to the direction X; In the input member for a touch panel in which the electrode of the first electrode sheet and the electrode of the second electrode sheet are insulated from each other, the first electrode sheet is obtained from the transparent wiring sheet according to [1] An input member for a touch panel, characterized in that there is.

The transparent wiring sheet of the present invention can easily increase the yield of the electrode sheet, can easily reduce the dimensional deviation from the paired electrode sheet when used as an electrode sheet, and is used as an input member for a touch panel. A sufficiently high coordinate detection accuracy can be ensured.
According to the method for producing a transparent wiring sheet of the present invention, the transparent wiring sheet can be easily produced.
The touch panel input member of the present invention can detect coordinates correctly.

It is a top view which shows the 1st transparent wiring sheet which is one Embodiment of the transparent wiring sheet of this invention. It is a fragmentary sectional view of the 1st transparent wiring sheet and the 2nd transparent wiring sheet. It is an electron micrograph of parts other than the insulating part of a transparent conductive layer. It is an electron micrograph of the insulating part of a transparent conductive layer. It is a top view which shows the 2nd transparent wiring sheet combined with the 1st transparent wiring sheet of FIG. It is a schematic diagram explaining the transparent conductive layer formation process which comprises the manufacturing method of the transparent wiring sheet of this invention. It is a schematic diagram explaining the electrode formation process which comprises the manufacturing method of the transparent wiring sheet of this invention. It is sectional drawing which shows one Embodiment of the input member for touchscreens of this invention. It is a top view which shows the overlapping state of the 1st electrode sheet and the 2nd electrode sheet in the input member for touch panels of FIG. It is a figure explaining the input of the coordinate input device using the input member for touchscreens of this invention.

<Transparent wiring sheet>
An embodiment of the transparent wiring sheet of the present invention will be described.
1 and 2 show a transparent wiring sheet of the present embodiment. The first transparent wiring sheet 1 of the present embodiment includes a transparent insulating substrate 10 and a transparent conductive layer 20 provided on one surface of the transparent insulating substrate 10, and has a rectangular input near the center in plan view. The area is divided into an area A ₁ and a routing wiring area A ₂ arranged outside the input area A ₁ .
The first transparent wiring sheet 1 is combined with the second transparent wiring sheet 2 as an input member for a touch panel, as will be described later.
In the present invention, “transparent” means that the light transmittance measured according to JIS K7105 is 50% or more. “Insulation” means that the electric resistance value is 1 MΩ or more, preferably 10 MΩ or more, and “conducting” means that the electric resistance value is less than 1 MΩ.

(Transparent insulating substrate)
Examples of the material of the transparent insulating substrate 10 include glass, polycarbonate, polyester such as polyethylene terephthalate (PET), acrylic resin, and the like.
The thickness of the transparent insulating substrate 10 is preferably 10 to 250 μm, and more preferably 25 to 188 μm. If the thickness of the transparent insulating substrate 10 is equal to or greater than the lower limit value, sufficient strength and rigidity can be ensured, and if the thickness is equal to or smaller than the upper limit value, the touch panel can be easily thinned.

(Transparent conductive layer)
The transparent conductive layer 20 contains a layered transparent substrate B and conductive ultrafine fibers W arranged in a two-dimensional network inside the transparent substrate B (see FIG. 3). Specifically, the transparent conductive layer 20 is formed by applying a fiber dispersion containing conductive fine fibers along one direction α to form a two-dimensional network of conductive fine fibers, and then, on the two-dimensional network, It is formed by applying a transparent substrate paint containing a transparent substrate.
The transparent conductive layer 20 in the input area A _1, the first is insulated line L ₁ is formed, is provided with a plurality of first electrode 21a. Specifically, the first insulating line L ₁ on the transparent conductive layer 20 is, in a zigzag along the direction X as the conductive portion of the plurality of substantially square shape along the direction X electrodes form linked at its corners is obtained A first electrode 21a having a so-called diamond pattern is provided. The aspect ratio of the first electrode 21a is more than 1, preferably 5 or more, and more preferably 7 or more. The aspect ratio of the first electrode 21a is preferably 400 or less. Here, the aspect ratio is the length of the electrode / the average width of the electrode. An electrode with an aspect ratio of 1 is difficult to apply to a projected capacitive touch panel.
The first electrode 21a is arranged perpendicular to the fiber dispersion application direction α. Here, “vertical” includes not only that the angle between the application direction α of the fiber dispersion and the longitudinal direction of the first electrode 21a is 90 °, but also that the angle is 90 ± 30 °.

The adjacent first electrodes 21a, 21a that are parallel to each other are not conductive. The first electrode 21a adjacent, between 21a each other, the second insulation line L ₂ is formed, fine conductive parts 22 is provided with a not conductive with the first electrode 21a. Portions other than the first electrode 21 a and the micro conductive portion 22 in the input area A ₁ are isolated conductive portions 23 that are not electrically connected to the first electrode 21 a and the micro conductive portion 22.
The first electrodes 21a of the first transparent wiring sheet 1 are formed so as not to overlap each other when used as an input member in combination with a second electrode 21b of the second transparent wiring sheet 2 described later.
The boundary between the input areas A ₁ and the lead wiring area A _2, the third insulating line L ₃ are formed.

  As described above, the diamond-patterned first electrode 21a is alternately formed with the wide portions 21c and the narrow portions 21d narrower than the wide portions 21c along the longitudinal direction thereof. That is, the wide portions 21c and the narrow portions 21d are alternately formed perpendicular to the application direction α. When the wide portion 21c is provided, the wiring resistance is reduced, so that the electrical resistance of each first electrode 21a is smaller than that of a certain width.

A lead wiring area A ₂ of the transparent conductive layer 20 projects from the input area A _1, the one end electrically connected to the relay terminal portion 25 of the first electrode 21a are formed. If the relay terminal portion 25 is formed, a routing circuit 30 to be described later can be easily connected to a low resistance.
Further, the lead wiring area A ₂ of the transparent conductive layer 20 projects from the input area A _1, the test terminal section 26 which is electrically connected to the other end of the first electrode 21a is provided with a plurality. Here, the inspection terminal portion 26 is made of a low resistance material formed of ink or paste containing a conductive substance. It does not restrict | limit especially as an electroconductive substance, Particle | grains or fibers, such as a metal, an electroconductive metal oxide, and an electroconductive polymer, are mentioned. Since the inspection terminal portion 26 can reduce the contact resistance with the inspection probe, the inspection accuracy can be improved by conducting the continuity inspection using the inspection terminal portion 26.

Further, the lead wiring area A ₂ is a signal obtained by the first electrode 21a, the routing for connection to an external circuit (not shown) that is external to the transparent wiring sheet 1 from the relay terminal portion 25 A plurality of circuits 30 are provided. The routing circuit 30 includes a routing wire 31 connected to the relay terminal portion 25 and an external connection terminal portion 32 connected to the routing wire 31. The routing circuit 30 is made of a low resistance material formed of ink or paste containing a conductive substance. It does not restrict | limit especially as an electroconductive substance, Particle | grains or fibers, such as a metal, an electroconductive metal oxide, and an electroconductive polymer, are mentioned.
Further, in the transparent conductive layer 20 in the routing wiring area A ₂ , a fourth insulating line L _{4 for} insulating the routing circuits 30 and 30 adjacent to each other so as not to be conducted through the transparent conductive layer 20 is provided in each routing circuit 30. It is formed in the vicinity. Further, the transparent conductive layer 20 of the lead wiring area A in _2, the fifth insulating line which L ₅ are formed in a lattice shape. When the fifth insulating line L ₅ grid on the transparent conductive layer 20 of the lead wiring area A in ₂ is formed, upon the input member of the touch panel overlapping the transparent wiring sheet 1 as will be described later, Crosstalk between the routing circuits 30 and 30 adjacent to each other can be suppressed.

The first insulating line L ₁ , the second insulating line L ₂ , the third insulating line L ₃ , the fourth insulating line L ₄ and the fifth insulating line L ₅ are made of conductive fine fibers without melting the transparent substrate B. The void V is formed by evaporation and removal (see FIG. 4), and the transparent substrate remains. Therefore, since the conductive region and the optical properties includes a conductive ultrafine fibers are substantially equal, the pattern in the input area A ₁ has become less visible. Therefore, it is suitable as an input member for a touch panel installed on the image display device.

The widths of the first insulating line L ₁ , the second insulating line L ₂ , the third insulating line L ₃ , the fourth insulating line L _4, and the fifth insulating line L ₅ depend on the wavelength of the irradiated laser light, but are usually 10 to 100 μm. When an insulating line having a width of 100 μm is formed by laser irradiation, the irradiation may be performed in a plurality of times.

The conductive ultrafine fibers contained in the transparent conductive layer 20 are irregularly present along the surface direction of the surface of the transparent insulating base material 10 so as to face a random direction, and at least some of them are in contact with each other. They are arranged in a two-dimensional mesh so densely as to fit. With such an arrangement, the conductive microfibers are electrically connected to each other to form a conductive network structure.
In addition, most of the conductive ultrafine fibers are embedded in the transparent substrate, but a part of the fibers protrudes from the surface of the transparent substrate.

  Conductive ultrafine fibers include metal nanowires and metal nanotubes made of copper, platinum, gold, silver, nickel, etc., fibrous members such as silicon nanowires and silicon nanotubes, metal oxide nanotubes, carbon nanotubes, carbon nanofibers, and graphite fibrils And the metal-coated member thereof. Among these, the metal nanowire (silver nanowire) which has silver as a main component from a transparency and electroconductivity point is preferable. The conductive ultrafine fiber preferably has a diameter of 0.3 to 100 nm and a length of 1 to 100 μm.

As a resin for forming a transparent substrate, transparent thermoplastic resin (polyvinyl chloride, vinyl chloride-vinyl acetate copolymer, polymethyl methacrylate, nitrocellulose, chlorinated polyethylene, chlorinated polypropylene, vinylidene fluoride), heat, Examples thereof include transparent curable resins (silicone resins such as melamine acrylate, urethane acrylate, epoxy resin, polyester resin, polyimide resin, and acrylic-modified silicate) that are cured by active energy rays (ultraviolet rays, electron beams, radiation).
The transparent substrate is preferably made of the same material as that of the transparent insulating substrate 10 in terms of adhesiveness and transparency. For example, when the transparent insulating substrate is a polyethylene terephthalate film, it is preferable to select a polyester resin as the transparent substrate.

(Outline mark, positioning mark)
The transparent conductive layer 20 has an input area A ₁ and the lead wiring area A ₂ external mark 27 visible surrounding the provided. Further, the lead wiring area A ₂ is used for alignment when stacking the first transparent wiring sheet 1 and the second transparent wiring sheet 2, the first positioning mark 28 is provided visible. The transparent conductive layer 20 is provided with a visually recognizable second positioning mark 29 that is used for alignment when the routing circuit 30 is printed outside the outer shape mark 27.

(Second transparent wiring sheet)
Similar to the first transparent wiring sheet 1, the second transparent wiring sheet 2 paired with the first transparent wiring sheet 1 is a transparent insulating substrate 10 and a transparent conductive layer 20 provided on one side of the transparent insulating substrate 10. And is divided into a rectangular input area A ₁ near the center in plan view and a routing wiring area A ₂ arranged outside the input area A ₁ .
Dadashi, second transparent wiring sheet 2, the transparent conductive layer 20 in the input area A _1, a first insulation line L ₁ is formed, is provided with a plurality of second electrodes 21b. Specifically, as shown in FIG. 5, the first insulating line L ₁ on the transparent conductive layer 20 is formed along the direction Y so that the wide portion 21c and the narrow portion 21d is obtained, so-called diamond pattern The second electrode 21b is provided. Also in the second electrode 21b, the aspect ratio is more than 1, preferably 5 or more, and more preferably 7 or more. The second electrode 21b is provided in parallel to the application direction α of the fiber dispersion, and the second transparent wiring sheet 2 is not the transparent wiring sheet of the present invention.
Further, the second transparent wiring sheet 2 has a longest length longer than that of the first transparent wiring sheet 1.

In addition, in the second transparent wiring sheet 2, the minute conductive portion 22 and the isolated conductive portion 23 are formed by the second insulating line L ₂ . Further, the third insulating line L _3, the boundary between the wiring area A ₂ and the input area A ₁ routing is partitioned. The fifth insulating line L ₅ grid is provided.
Further, the lead wiring area A ₂ is the routing circuits 30 are provided.
Further, the lead wiring area A ₂ of the transparent conductive layer 20, electrically connected to the relay terminal portion 25 is formed with a plurality, is electrically connected to the other end of the second electrode 21b to one end of the second electrode 21b A plurality of inspection terminal portions 26 are provided.
Further, provided external mark 27 surrounding the input area A ₁ and the lead wiring area A _2, the lead wiring area A _2, the first positioning mark 28 and the second positioning mark 29 is provided.

<Method for producing transparent wiring sheet>
Next, the manufacturing method of the said transparent wiring sheets 1 and 2 is demonstrated.
The manufacturing method of the transparent wiring sheets 1 and 2 of this embodiment has a transparent conductive layer formation process, a 1st electrode formation process, a 2nd electrode formation process, a mark formation process, and a routing circuit formation process.

(Transparent conductive layer forming process)
In the transparent conductive layer forming step, a fiber dispersion liquid containing conductive fine fibers is applied along one direction α on one surface side of the transparent insulating substrate 10 to form a two-dimensional network of conductive fine fibers. The transparent conductive layer 20 is formed by applying a transparent substrate paint including a transparent substrate on the two-dimensional network. The transparent insulating base material 10 used in the present embodiment is a long film having a width that allows the first transparent wiring sheet 1 and the second transparent wiring sheet 2 to be arranged in parallel.
When a long film is used as the transparent insulating base material, as shown in FIG. 6, the transparent insulating base material 10 is continuously fed out from the winding roll 51 of the transparent insulating base material, and fiber dispersion is performed using the coating device 52. The liquid is continuously applied and dried using a dryer 53 to obtain a fiber laminated sheet 54 in which a two-dimensional network of conductive ultrafine fibers is formed. Thereafter, a transparent base coating material is continuously applied on a two-dimensional network of conductive ultrafine fibers using a coating device, and then dried using a dryer to form a transparent conductive layer, thereby forming a conductive sheet 58. Get. When the fiber dispersion is applied in this way, the longitudinal direction of the transparent insulating substrate is the application direction α.
Alternatively, the fiber laminated sheet is wound up once, and as shown in FIG. 6, the fiber laminated sheet 54 is again fed out from the take-up roll 55 of the fiber laminated sheet, and the coating device is placed on the two-dimensional network of conductive microfibers The transparent conductive layer may be formed by continuously applying the transparent substrate paint using 56 and then drying using the dryer 57. Even in this case, the longitudinal direction of the transparent insulating substrate is the coating direction α.
The application direction of the transparent substrate paint may be the short direction of the transparent insulating substrate. If screen printing or the like is applied, it is possible to set the direction of application of the transparent substrate paint to the short direction of the transparent insulating substrate.

Examples of the coating devices 52 and 56 used when applying the fiber dispersion and the transparent base coating material include a die coater, a gravure coater, a reverse roll coater, a kiss coater, a roll knife coater, and a bar coater (rod coater). Or a spray or screen printer can be used. Among these, when a coating machine is used, since the transparent conductive layer is easily damaged, the effect of the present invention is more exhibited.
As the dryers 53 and 57, a hot air dryer, an infrared dryer, a vacuum dryer, or the like can be applied.

(First electrode forming step)
As shown in FIG. 1, the first electrode forming step is a step of forming a plurality of first electrodes 21 a on the transparent conductive layer 20 perpendicular to the fiber dispersion application direction α. Specifically, in the electrode forming step, after a conductive sheet having the transparent conductive layer 20 formed on one side of the transparent insulating base material 10 is placed on the stage, the transparent conductive layer 20 is emitted from the laser light generating means and collected. The laser beam condensed by the optical means is irradiated so that the focal point is located. The laser light irradiation pattern is a pattern in which the first insulating line L ₁ , the second insulating line L ₂ , the third insulating line L ₃ , the fourth insulating line L _4, and the fifth insulating line L ₅ are formed. A plurality of first electrodes 21 a is formed by forming the first insulating line L ₁ in the transparent conductive layer 20. In this manufacturing method, the first electrode 21a is formed perpendicular to the application direction α of the fiber dispersion (that is, the longitudinal direction of the transparent insulating base material 10) and the direction perpendicular to the application direction α (the longitudinal direction of the first electrode 21a). ) To form a diamond pattern.
In the first electrode forming step in the present embodiment, the second transparent wiring sheet 2 can be formed in parallel with the first transparent wiring sheet 1 in the width direction of the conductive sheet 58, and the first transparent wiring is formed along the longitudinal direction. The first electrodes 21a are formed in such an arrangement (see FIG. 7) that the sheets 1 and the second transparent wiring sheets 2 can be alternately formed.

Furthermore, form minute conductive portion 22 and the isolated conductive portion 23 by forming the second insulation line L _2. Further, the boundary line between the input area A ₁ and the lead wiring area A ₂ is formed by forming the third insulating line L ₃ . Also, insulation between the routing circuits 30, 30 by forming a fourth insulating line _{L 4.} Further, to form a lattice-like insulating line lead wiring area A ₂ by forming a fifth insulating line L _5.
In the electrode forming step, in order to irradiate the conductive sheet 58 with the laser beam with a target pattern, a method of scanning the laser beam using a galvano mirror, a method of sliding the stage two-dimensionally, or the like can be applied. .

Examples of the laser light used in this manufacturing method include pulsed laser light such as YAG and YVO ₄ and continuous wave laser light such as a carbon dioxide gas laser. Among these, a pulsed laser beam having a wavelength of 1064 nm such as YAG or YVO ₄ or a second harmonic thereof and a pulse width of 1 to 200 nsec is preferable because it is simple. For applications in which the laser irradiation trace is not conspicuous, an ultrashort pulse laser having a wavelength of 1600 to 600 nm and a pulse width of 10 f to 100 p seconds is preferable.
In the pulsed laser, it is preferable to irradiate the conductive substrate while moving the position of the spot of the laser beam little by little so that the spots overlap each other.

  In the portion of the transparent conductive layer 20 irradiated with the laser light, the conductive ultrafine fibers are evaporated and removed without melting the transparent substrate, so that voids are formed. In this gap, there is no contact between the conductive ultrafine fibers, and the conductive network is disconnected, so that an insulating line is formed.

The insulating line is formed by a pulsed laser, and its pulse width is sufficiently shorter than the scanning speed. Therefore, the focused spot is substantially circular, and the width of the insulated line is equal to the focused spot diameter.
The irradiation energy density per pulse of the laser beam is defined as the irradiation energy per pulse of the laser beam divided by the focused spot area. The value is 1 × 10 ⁴ to 1 × 10 ⁵ J / m ² regardless of the wavelength of the laser beam when the pulse width is in the range of 10 fsec to 200 nsec.
In addition, in order to form a continuous insulating line, it is necessary that individual focused spots formed by moving by scanning overlap each other. In particular, in a transparent conductive layer including silver nanowires, only silver nanowires are present. It is preferable to set the number of overlaps to about 1.5 to 10 in that it can be surely removed and the insulation line can hardly be visually recognized and the stability of insulation can be achieved. In addition, when the outer shape mark 27, the first positioning mark 28, and the second positioning mark 29 are intended to be visually recognized, the number of overlaps is set to 25 times or more, or the overlap is performed by scanning a plurality of times. The number of times is preferably 25 times or more.

The stage on which the conductive sheet is disposed is preferably a light scattering and opaque plate. Here, the term “opaque” means that the light transmittance measured according to JIS K7105 is 10% or less. Examples of the light-scattering and opaque plate include a plate with irregularities formed on the surface, a plate containing filler or air inside, and a plate coated with colored ink on the surface.
The transparent conductive layer 20 is transparent, and it is difficult to adjust the focus (condensing point of laser light). However, when using a light-scattering and opaque plate as the stage, the transparent conductive layer 20 is focused and irradiated with laser light by focusing on the opaque stage in the electrode forming step. be able to.
Moreover, it is preferable that the stage can be sucked in order to fix the conductive sheet.

(Second electrode forming step)
In the second electrode forming step, as shown in FIG. 7, the second electrode 21b is arranged in parallel to the transparent conductive layer 20 with its longitudinal direction parallel to the coating direction α and insulated from the first electrode 21a. It is the process of forming so that it may be performed. Specifically, in the second electrode forming step, after the conductive sheet 58 is arranged on the stage, the light is emitted from the laser light generating means to the portion of the transparent conductive layer 20 where the first electrode 21a is not formed, and the light collecting means The laser beam condensed by the above is irradiated so that the focal point is located. The laser light irradiation pattern is a pattern in which the first insulating line L ₁ , the second insulating line L ₂ , the third insulating line L ₃ , the fourth insulating line L _4, and the fifth insulating line L ₅ are formed. A plurality of second electrodes 21 b are formed by forming the first insulating lines L ₁ in the transparent conductive layer 20. In this manufacturing method, the second electrode 21b is formed in parallel with the application direction α of the fiber dispersion (that is, the longitudinal direction of the transparent insulating base material 10) and parallel to the application direction α (the longitudinal direction of the second electrode 21b). ) To form a diamond pattern. “Parallel” here means not only that the angle between the application direction α of the fiber dispersion and the longitudinal direction of the second electrode 21b is 0 °, but also that the angle is 0 ± 30 °.
The second electrode forming step, it is possible to align the first longitudinal direction of the input area A ₁ of the transparent wiring sheet 1 longitudinally of the input area A ₁ of the second transparent wiring sheet 2.
The second electrode forming step may be performed simultaneously with the first electrode forming step or may be performed separately. However, in either case, in the manufacturing method of the present embodiment, the first electrode 21a and the second electrode 21b are arranged in parallel in the width direction of the conductive sheet 58, and the first electrode 21a and the second electrode along the longitudinal direction. The two electrodes 21b are alternately formed.

(Mark formation process)
In the mark forming step, laser light is irradiated onto the conductive substrate in a pattern in which the outer shape mark 27, the first positioning mark 28, and the second positioning mark 29 are formed. In this step, in order to make the outer shape mark 27, the first positioning mark 28, and the second positioning mark 29 visible, the transparent substrate is colored by irradiating laser light with higher energy than in the electrode forming step. As a method of irradiating the laser beam with higher energy than the electrode forming step, a method of slowing the scanning speed of the laser beam, a method of irradiating the laser beam to the same position several times, a method of increasing the output of the laser beam, a long focal length And a method of irradiating the laser beam condensed by the optical system.
Note that the mark formation step may be performed at any timing, for example, before or after the first electrode formation step and the second electrode formation step, or between the first electrode formation step and the second electrode formation step. Good.

(Leading circuit formation process)
Routing circuits forming step is a step of forming a routing circuit 30 to the lead wiring area A _2. A specific method of forming the routing circuit 30 includes a method of printing or applying an ink or paste containing a conductive substance between the fourth insulating lines L ₄ and L ₄ . Among the printing / coating methods, the screen printing method is preferable. Usually, after coating, a drying process or a baking process is performed to obtain the routing circuit 30. Thereby, a long transparent wiring sheet is obtained.
Thereafter, the transparent wiring sheets 1 and 2 are obtained by punching into a predetermined size.

(Function and effect)
In the above embodiment, the first transparent wiring sheet 1 and the second transparent wiring sheet 2 having different lengths are used in order to make the first electrode 21a perpendicular to the coating direction α and the second electrode 21b parallel to the coating direction α. It is easy to arrange them at close intervals. Therefore, the remaining part after punching, that is, the part to be discarded is reduced, and the yield is increased.
Further, at the time of forming the second transparent wiring sheet 2 to form a first transparent wiring sheet 1 to the conductive sheet 58, the input area A ₁ of the first transparent wiring sheet 1 in the longitudinal direction and the second transparent wiring sheet 2 since the longitudinal direction of the input area a ₁ is aligned, can be a transparent insulating substrate 10 is easily reduced the deviation of the dimension between the pair of electrode sheets be contracted in the longitudinal direction. Thereby, when it uses for the input member of a touch panel, sufficiently high coordinate detection accuracy is securable.

The diamond-patterned first electrode 21a is formed by alternately arranging the wide portions 21c and the narrow portions 21d along the direction perpendicular to the coating direction α, and has a resistance higher than that of an electrode having a constant width. It is getting smaller.
In the case of an electrode having a constant width, the coordinate detection accuracy of the input member may be insufficient when the longitudinal direction thereof is perpendicular to the direction of application of the conductive fine fiber dispersion. This is presumed to be one of the causes that the resistance value of the electrode perpendicular to the coating direction is about twice the resistance value of the electrode parallel to the coating direction, resulting in a large anisotropy in electrical resistance.
In the present embodiment, the conductive ultrafine fibers in the transparent conductive layer 20 are oriented along the application direction α, and the conductive ultrafibers in the first electrode 21a are perpendicular to the application direction α. Since the 21c and the narrow portion 21d are alternately formed and the resistance value of the first electrode 21a is small, the ratio (or difference) with the resistance value with respect to the second electrode 21b is small. That is, the anisotropy of electrical resistance is suppressed. Therefore, when used as an input member of a touch panel, sufficiently high coordinate detection accuracy can be ensured.

<Input material for touch panel>
Next, an input member for a touch panel (hereinafter referred to as “input member”) using the transparent wiring sheets 1 and 2 will be described.
As shown in FIGS. 8 and 9, the input member 100 of the present embodiment includes a first electrode sheet 110 in which a first electrode 111 for coordinate detection is provided along the direction X, and a second electrode for coordinate detection. 121 has the 2nd electrode sheet 120 provided along the direction Y perpendicular | vertical with respect to the said direction X, and the protective material 130 arrange | positioned at the surface side. The first electrode sheet 110 and the second electrode sheet 120 are bonded by an insulating transparent adhesive 140, and the first electrode 111 and the second electrode 121 are insulated from each other. Further, the first electrode sheet 110 and the protective material 130 are bonded by an insulating transparent adhesive 150.
In the present embodiment, the first electrode sheet 110 is the first transparent wiring sheet 1, and the second electrode sheet 120 is the second transparent wiring sheet 2. Accordingly, the first electrode 111 is the first electrode 21 a of the first transparent wiring sheet 1, and the second electrode 121 is the second electrode 21 b of the second transparent wiring sheet 2.
As the protective material 130, various transparent resin films and glass plates can be used.

In coordinate detection using this input member 100, one of the second electrodes 121 is selected by switch means for switching electrodes, a rectangular pulse is input from a rectangular pulse generator, and a differential pulse waveform emitted from the first electrode 111 is generated. Observe. The second electrode 121 for inputting the rectangular pulse is sequentially switched by the switch means, and the differential pulse waveform from each first electrode 111 is observed. Further, one of the first electrodes 111 is selected by switch means for switching electrodes, a rectangular pulse is input from the rectangular pulse generator, and a differential pulse waveform emitted from the second electrode 121 is observed. The first electrodes 111 that send rectangular pulses are sequentially switched by the switch means, and the differential pulse waveforms output from the second electrodes 121 are observed.
When the user of the touch panel performs input, as shown in FIG. 10, the finger F is brought into contact with the surface of the protective material 130 (the surface on the input user side). At this time, capacitive coupling is formed between the finger F and the first electrode 111, and capacitive coupling is formed between the finger F and the second electrode 121 via the first electrode 111.
In the portion where the finger F is in contact, the coupling capacitance between the first electrode 111 and the second electrode 121 increases. Therefore, the differential pulse waveform obtained from the first electrode 111 or the second electrode 121 near the finger F is large. By detecting the variation of the differential pulse waveform, the X coordinate and the Y coordinate can be obtained.

  Since the input member 100 of the present embodiment can easily reduce the dimensional deviation between the first electrode sheet 110 and the second electrode sheet 120, the coordinates can be detected correctly.

<Other embodiments>
In addition, this embodiment is not limited to the said embodiment.
For example, the shape of the electrode may not be a plurality of substantially square wide portions, and may be, for example, a substantially circular wide portion. Further, the electrode in the present invention may have a rectangular shape without forming the wide portion and the narrow portion.
Further, a routing circuit made of a low resistance material may be omitted. When a routing circuit made of a low resistance material is omitted, the transparent conductive layer in the routing wiring area may be processed with a laser beam so that a routing wiring is formed.
Moreover, the transparent wiring sheet of this invention does not need to form the terminal part for a relay in the transparent conductive layer of a routing wiring area, and does not need to form the terminal part for an inspection.
In addition, the portion of the transparent conductive layer that is insulated in a pattern may not be one obtained by evaporating and removing conductive ultrafine fibers by laser light irradiation. For example, a conductive ultrafine fiber may be cut and insulated. Further, a pattern may be formed by lift-off or plasma irradiation using a mask opened in a pattern.
Moreover, although the transparent wiring sheets 1 and 2 of the said embodiment were what can be used as an electrode sheet as they are, the transparent wiring sheet of this invention is a long transparent wiring sheet which has a margin area outside a routing wiring area. It may be. That is, the long transparent wiring sheet before punching in the manufacturing method is also included in the transparent wiring sheet of the present invention.

Moreover, in the manufacturing method of a transparent wiring sheet, you may use a sheet glass plate and a film as a transparent insulating base material in a transparent conductive layer formation process. Even if the obtained transparent wiring sheet 1 is a single sheet cut out from a long sheet, the same effect can be obtained as long as the application direction α is managed so as to be discriminated. However, in the case of a long film as in the above embodiment, the effects of the present invention are particularly exhibited, which is preferable.
Moreover, in the manufacturing method of a transparent wiring sheet, you may form the 1st electrode 21a and the 2nd electrode 21b separately in the different conductive sheet 58 at a 1st electrode formation process and a 2nd electrode formation process. Even in this case, the yield can be increased by using the conductive sheet 58 having an appropriate width. Moreover, since the longitudinal direction of an input area can be arrange | equalized, even if a transparent insulating base material shrink | contracts along a longitudinal direction, the shift | offset | difference of the dimension of a 1st transparent wiring sheet and a 2nd transparent wiring sheet can be made small.

In the input member of the present invention, one of the first electrode sheet and the second electrode sheet may not be the transparent wiring sheet of the present invention.
Further, as another input member using the transparent wiring sheet of the present invention, each transparent conductive layer in the input area is provided with a transparent insulating base and transparent conductive layers provided on both sides of the transparent insulating base. In which an electrode having an aspect ratio of more than 1 is formed. The transparent conductive layer in the input member is formed in the same manner as described above, and one electrode and the other electrode are arranged perpendicular to each other, and only one electrode is perpendicular to the coating direction α.

Example 1
A 125 μm-thick polyethylene terephthalate film (PET film) wound in a roll shape was fed out, and a diluted solution of a silver nanowire dispersion (Clear Ohm manufactured by Cambrios) was continuously applied to one side of the film using a die coater. Next, the coated silver nanowires were dried using an infrared dryer to produce a fiber laminated sheet, which was wound up.
Subsequently, the wound fiber laminated sheet was fed out, and an ultraviolet curable acrylic resin was applied using a die coater and cured by ultraviolet irradiation to form a transparent conductive layer. Thereafter, a protective film was superimposed on the exposed surface of the PET film, wound up, and further slitted at both ends so that the width was 500 mm to obtain a conductive sheet. The width direction center part of the obtained electroconductive sheet was cut out by width 10mm and length 100mm, and the surface resistance of the transversal direction and the surface resistance of the longitudinal direction of the obtained film piece were measured. As a result, the surface resistance in the longitudinal direction was 81 Ω / □, and the surface resistance in the short direction was 166 Ω / □ (2.05 times the longitudinal direction). Further, the light transmittance was measured and found to be 95%.
In the obtained conductive sheet, a second electrode in which a first electrode sheet having an aspect ratio of more than 1 is formed and a second electrode having an aspect ratio of more than 1 perpendicular to the first electrode is formed. An insulating line was formed by irradiating a laser beam so that a region to be an electrode sheet was formed, and a long transparent wiring sheet was obtained. At this time, the first electrode was formed perpendicular to the coating direction (longitudinal direction of the PET film), and the second electrode was formed parallel to the coating direction. Further, the first electrode and the second electrode were formed in parallel in the width direction of the conductive sheet so as to be in an insulating state, and the first electrode and the second electrode were alternately formed along the longitudinal direction.
Subsequently, a relay terminal portion was formed at one end of each of the first electrode and the second electrode by screen printing of a conductive paste, and an inspection terminal portion was provided at the other end.

The electric resistance value (namely, average value) per one obtained first electrode was 4.65 kΩ, and the electric resistance value of the unit length of the first electrode was 581Ω. Here, the unit length is the length between the widest portions in the adjacent conductive portions.
On the other hand, the electric resistance value (that is, the average value) per one second electrode was 3.34 kΩ, and the electric resistance value of the unit length of the second electrode was 334Ω.
Therefore, the ratio of the electrical resistance value of the unit length of the first electrode to the electrical resistance value of the unit length of the second electrode is 1.74, and the anisotropy of electrical resistance is suppressed compared to the conductive sheet. It was.
Further, it is possible to align the first longitudinal direction of the input area A ₁ of the transparent wiring sheet 1 longitudinally of the input area A ₁ of the second transparent wiring sheet 2 easily, less discarded in part after the punching And the yield increased. Furthermore, even if the transparent insulating base material contracted in the longitudinal direction, the dimensional deviation between the pair of sheets could be easily reduced.

DESCRIPTION OF SYMBOLS 1, 2 Transparent wiring sheet 10 Transparent insulation base material 20 Transparent conductive layer 21a 1st electrode 21b 2nd electrode 21c Wide part 21d Narrow part 22 Micro conductive part 23 Isolated conductive part 25 Relay terminal part 26 Inspection terminal part 27 Outline Mark 28 First positioning mark 29 Second positioning mark 30 Leading circuit 31 Leading wiring 32 External connection terminal part 51 Winding roll of transparent insulating base material 52, 56 Coating device 53, 57 Dryer 54 Fiber laminated sheet 55 Fiber laminated sheet Winding roll 58 conductive sheet 100 input member 110 first electrode sheet 111 first electrode 120 second electrode sheet 121 second electrode 130 protective material 140, 150 transparent adhesive A ₁ input area A ₂ routing wiring area B transparent substrate L ₁ first insulation line L ₂ second insulating line L ₃ third insulating line ₄ fourth insulating line L ₅ fifth insulating line V gap W conductive ultrafine fibers

Claims (10)

An input area provided in the center in a plan view, and a routing arranged outside the input area, comprising a transparent insulating base material and a transparent conductive layer provided on one surface side of the transparent insulating base material A transparent wiring sheet having a wiring area, the transparent conductive layer in the input area is insulated in a pattern, and a plurality of first electrodes for coordinate detection are formed,
The transparent conductive layer is formed by applying a fiber dispersion containing conductive fine fibers along one direction α to form a two-dimensional network of conductive fine fibers, and then transparently containing a transparent substrate on the two-dimensional network. A transparent wiring sheet, characterized in that it is a layer formed by applying a base paint, and the first electrode is formed perpendicular to the direction α and has an aspect ratio of more than 1. .   2. The transparent wiring sheet according to claim 1, wherein the first electrode is formed such that a wide portion and a narrow portion narrower than the wide portion are alternately formed along a longitudinal direction thereof.   The portion of the transparent conductive layer insulated in a pattern is characterized in that the transparent conductive layer is irradiated with laser light in a pattern, and the conductive ultrafine fibers are evaporated and removed without melting the transparent substrate. The transparent wiring sheet according to claim 1 or 2.   The transparent wiring sheet according to any one of claims 1 to 3, wherein the transparent insulating substrate is a long film, and the longitudinal direction of the film is the direction α. On one side of the transparent insulating base material, a fiber dispersion containing conductive fine fibers is applied along one direction α to form a two-dimensional network of conductive fine fibers, and then on the two-dimensional network. A transparent conductive layer forming step of forming a transparent conductive layer by applying a transparent substrate coating containing a transparent substrate;
A first electrode forming step of insulating the transparent conductive layer in a pattern and forming a plurality of first electrodes having an aspect ratio of more than 1 so that the longitudinal direction thereof is perpendicular to the direction α;
A method for producing a transparent wiring sheet, comprising:   6. The first electrode forming step according to claim 5, wherein the first electrode is formed such that wide portions and narrow portions narrower than the wide portions alternate along the longitudinal direction. The manufacturing method of the transparent wiring sheet of description.   In insulating the pattern of the transparent conductive layer in the first electrode formation step, the transparent conductive layer is irradiated with a laser beam in a pattern to evaporate and remove the conductive ultrafine fibers without melting the transparent substrate. The manufacturing method of the transparent wiring sheet of Claim 5 or 6.   The method for producing a transparent wiring sheet according to claim 5, wherein a long film is used as the transparent insulating substrate, and the longitudinal direction of the film is set to the direction α.   A portion of the transparent conductive layer where the first electrode is not formed is insulated in a pattern, and a plurality of second electrodes having an aspect ratio of more than 1 are arranged such that the longitudinal direction is parallel to the direction α and the first The method further comprises a second electrode forming step for forming electrodes so as to be arranged in parallel in an insulated state, wherein the first electrodes and the second electrodes are alternately arranged along the longitudinal direction of the transparent insulating base material. The method for producing a transparent wiring sheet according to claim 8. A first electrode sheet in which an electrode for coordinate detection is provided along a direction X; and a second electrode sheet in which an electrode for coordinate detection is provided along a direction Y perpendicular to the direction X. In the input member for a touch panel in which the electrode of the first electrode sheet and the electrode of the second electrode sheet are insulated from each other,
An input member for a touch panel, wherein the first electrode sheet is obtained from the transparent wiring sheet according to claim 1.