KR101560079B1 - Touch-sensitive panel device and electrode structure therein - Google Patents

Abstract

The present invention relates to a touch panel device and its electrode structure. The electrode structure can be made of a metal conductive material, effectively suppressing reflected metal light, and not affecting permeability and metal conductivity, A light-reducing rough structure, and a blackening layer. The electrode structure and the substrate are bonded to each other, and a rough structure is provided in the electrode structure. For example, the electrode structure is connected and formed on the surface of the metal conductive layer , The metal reflection light is scattered, or the composite reflection light of both the metal conductive layer and the substrate is lowered, and the formation of the mounting structure is formed by etching or processing on the metal conductive layer, or by electrolysis, sputtering, The blackening layer absorbs light rays incident on the metal conductive layer, reduces the color deviation from the screen, To prevent the light.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a touch panel device,

And more particularly, to a metal electrode structure having an antireflection function and a touch panel formed of the electrode structure.

In the prior art of panels using metal electrode wires (metal gratings), a separate layer of anti-glare film is required, thereby eliminating reflected metal light from the metal wires of the panel, May cause a problem of deteriorating the quality of the display.

The use of a conventional anti-glare film increases the thickness of the touch panel and may affect the light transmittance of the light-transmitting region; At the same time, the optical grade plastic substrate itself can also form reflected light, and the reflected light makes the eyes of the human eye easily tired, and when combined with the reflected light of the metal wire described above, the reflected light will be more interfered, You will easily observe the interference of metal wires.

FIG. 1 is a schematic view of a cross-sectional structure of a conventional touch-display device using a substrate and an electrode structure.

The touch panel part includes the substrate 10 and the electrode structures 101 and 102 on the upper and lower surfaces thereof. When a touch display is formed, an optically clear adhesive 11 is provided on the upper part, An anti-glare film 12 for removing the reflected light of the panel metallic material is attached to the upper substrate 11, and then the upper substrate 14 is attached with the optical adhesive 13 again. In the lower portion of such a structure, the substrate 10 can be placed on the liquid crystal display module 16 through the optical adhesive 15.

In the prior art, as a solution for lowering the metallic reflection light described above, for example, a blackening layer is plated on a structure of a metal (for example, copper) lattice, and the color aberration of the screen and the lattice structure However, such a blackening layer deteriorates the conductivity of the metal layer all the time, even if any metal or oxide layer is used, and the ability to resist environmental corrosion is also poor.

The stacked structure of the conductive electrode and the substrate of the touch panel of the related art can be referred to a schematic cross-sectional view shown in Fig.

Among them, the plastic substrate 21 of the panel is shown, and the first electrode 23 is formed on the upper part. Since this electrode structure generates metal reflection light as a metal material, the first blackening layer 25 is formed on the surface thereof When the incident light 201 is incident on the first electrode 23 as shown in the figure, the original reflected light 202 is incident on the first blackening layer 25 as a metallic reflected light; The incident light 203 is incident on the plastic substrate 21 and then reflected by the substrate as reflected light 204.

A second electrode 29 is formed on the other side of the plastic substrate 21 as shown in the figure and similarly a second blackening layer 27 is formed on the surface facing the outside of the second electrode 29 . As shown in the drawing, a light beam incident on the plastic substrate 21 is transmitted through the second electrode 29, and is reflected by the reflected light 205.

As described above, in the prior art, it is not effective to lower the chromatic aberration by using the anti-glare structure or to reduce the chromatic aberration of the metal and the screen by forming a blackening layer on the electrode structure. Problems such as increasing the thickness of the panel, lowering the covered metal conductivity, and lowering the resistance to corrosion are caused.

In the prior art, metal reflection light is generated using a metal electrode wire, the anti-glare film is directly coated on the electrode to lower the display quality of the panel, or to prevent the chromatic aberration problem of the metal and the screen through the blackened layer , And the problem of lowering the electric conductivity is rather created. In the specification of the present invention, the touch panel device, the electrode structure and the manufacturing process are disclosed. Among them, the design of the electrode structure can effectively reduce the thickness of the touch panel in addition to effectively removing reflected light generated from the metal or the substrate, And does not affect the display quality, has high light transmittance and metal conductivity, and at the same time has excellent weather resistance and can resist corrosion in an environment of high temperature salinity.

According to one embodiment, the main structure of the electrode structure is formed on the surface of the substrate, and the metal conductive layer is a conductive structure of the electrode structure; A light reducing coarse structure connected to the surface of the metal conductive layer and used for scattering reflected metal light or lowering the combined reflected light of the metal conductive layer and the substrate; And a blackening layer which is connected to the surface of the light-reducing rough structure and is used for absorbing the light incident on the metal conductive layer due to the light reducing action and at the same time does not cause incident light to be reflected in the same direction in which the incident light is reflected, Wherein the formation of the light-reducing rough structure may be formed by etching or processing on the metal conductive layer, or by an electrolytic, sputtering, deposition or coating method.

In the electrode structure described above, the electrode structure may further include an adhesive layer, and the electrode structure is used to bond with the substrate through the adhesive layer and improve adhesion between the electrode structure and the substrate; At the same time, the adhesive layer may have a light reducing rough structure.

In an embodiment of another electrode structure, the main structure comprises a black conductive layer having a metal conductive layer and a rough surface, in this embodiment the blackening layer is directly etched or worked to form a rough surface, and the blackening layer Scatter the reflected light formed by the metal conductive layer through the surface structure, and reduce the amount of reflected light. Similarly, an adhesive layer for improving the adhesiveness can be formed between the electrode structure and the substrate; At the same time, the adhesive layer may have a light reducing rough structure.

In the previously described embodiment, another blackening layer may be further formed on the surface of the blackening layer, thereby increasing the resistance to corrosion and blackening; Further, between the adhesive layer and the metal conductive layer, another adhesive layer for improving adhesion can be further formed; At the same time, the other adhesive layer may have a light reducing rough structure.

According to another embodiment of the electrode structure, the electrode structure mainly includes an adhesive layer, a metal conductive layer and a first blackening layer, and the first blackening layer is connected to the surface of the metal conductive layer, The second blackening layer is further formed on the surface of the first blackening layer to form a rough surface structure after the surface of the second blackening layer is etched or processed, The effect of suppressing the reflected light is strengthened, and the color deviation from the screen is reduced. The electrode structure of the embodiment of the present invention may include two or more adhesive layers, a blackening layer and a light-reducing coarse layer, and the present invention is not limited thereto.

The electrode structure described in each of the above embodiments combines with one substrate material and forms a combination of touch panel devices.

In another embodiment, a light-reducing coarse structure can likewise be formed on the surface of the substrate material, the main purpose of which is to effectively scatter light entering the substrate material, thereby effectively preventing visually uncomfortable reflected light.

In embodiments that form a light reducing coarse structure in the substrate material and the electrode structure described above, when bonding with other devices, an optical adhesive may be filled, and the optical adhesive may be applied to the surface of the light- It is possible to lower the height of the haze due to filling and light roughness and at the same time to make the color of the blackening layer having rough surface darker and to reduce the color deviation from the screen.

BRIEF DESCRIPTION OF THE DRAWINGS For a better understanding of the present invention, reference is made to the following detailed description of the present invention, the accompanying drawings, which are intended to provide a more in-depth understanding of the objects, features and advantages of the present invention, And the accompanying drawings and documents are for illustrative purposes only and are not intended to limit the present invention.

1 is a schematic cross-sectional view of a conventional touch display device.
2 is a schematic cross-sectional view of a layered structure of a conductive electrode and a substrate of a touch panel of the related art.
3 is a schematic view (1) of one embodiment of the basic electrode structure of the present invention.
4 is a schematic view (2) of one embodiment of the basic electrode structure of the present invention.
5 is a schematic view of another embodiment of the electrode structure of the present invention.
6A is a schematic view (1) of a substrate surface structure embodiment of the present invention.
6B is a schematic view (2) of a substrate surface structure embodiment of the present invention.
7A is a schematic view (1) of a combined embodiment of the electrode structure and substrate of the present invention.
7B is a schematic view (2) of an embodiment of the combination of the electrode structure and the substrate of the present invention.
8 is a schematic diagram of a touch panel embodiment of the present invention.
9 to 11 show an embodiment of the electrode structure of the present invention.
Fig. 12 is a flowchart for explaining the electrode structure manufacturing step.

The present invention relates to a touch panel device, an electrode structure and a manufacturing process, wherein a touch panel is made of metal or an electrode structure or wire based on metal, and the electrode structure is made of a metal material, It is possible to avoid the problem that the thickness of the structural layer for preventing reflected light in the conventional technique is increased and the problem that the conductivity is lowered by the general blackening treatment can be avoided, And a metal electrode wire for preventing reflected light that does not affect the metal conductivity.

In the touch panel device disclosed in the present invention, the main structure of the embodiment includes a transparent substrate and a metal electrode or wire on the substrate, and can be applied to a general touch panel or a flexible touch panel. Among them, a light-reducing rough structure is formed on the conductive metal surface, and the conductive metal surface is formed by etching or the like, or is formed by other methods such as electrolysis, sputtering, deposition, or coating. Further, a blackening layer can be further formed, and besides the energy of the reflected light is reduced, there is a function of optical matching and structure strengthening.

Based on the embodiment of the apparatus described in the specification, the light-reducing rough structure formed on the conductive metal or substrate surface is a thin layer, and the thickness of the layer is 1 nm to 10 μm, preferably 50 nm to 2 μm. The blackening layer formed on the surface of the conductive metal is intended to attain the purpose of lowering the energy of the reflected light. The characteristic of the blackening layer is a chromaticity coordinate formed by L (brightness), a (red green) and b The numerical range is L <50; a <-0.1; And b < -0.1.

First Embodiment:

3 is a schematic view of a basic electrode structure embodiment of the present invention. In the figure, an electrode structure 32 is formed on a substrate 30, and the basic structure of the electrode structure 32 includes a metal conductive layer 301, a light-reducing coarse layer 302 and a blackening layer 303). Among them, the structural features and fabrication can be referred to the description of FIG.

In the present embodiment, the electrode structure 32 is formed directly on the substrate 30 and includes an upper surface or a lower surface, the main structure of which is the metal conductive layer 301, As the main conductive structure of the structure 32, it can be formed on a specific structure by a method such as electrolysis, sputtering or printing.

In the method in which the metal acts as a conductive structure in the metal, since the metal easily reflects external light rays, application to the display device may be visually influenced. Therefore, in the present invention, means for roughening the electrode structure is added, There are various methods, one of which is to form and form the light-reducing rough layer 302 on the surface of the metal conductive layer 301, as described in this embodiment, For example, the surface of the metal conductive layer 301 may be subjected to a surface treatment, or a rough structural layer having a surface structure may be directly formed on the metal conductive layer 301. These surface structures can scatter the reflected light formed by the reflection on the metal conductive layer 301.

In this embodiment, a blackening layer 303 is then formed on the metal conductive layer 301 and the light-reducing coarse layer 302 and the blackening layer 303 is formed on the electrode structure 32, for example, the metal conductive layer 301 And the use thereof absorbs light rays incident on the electrode structure 32 from the outside and can reduce the color deviation particularly with respect to the screen and can function as a protective structure such as structure strengthening and corrosion resistance have.

Second Embodiment:

The schematic diagram of the basic electrode structure of the touch panel proposed in this specification can be referred to Fig. 4, and the manufacturing process steps can be concurrently referred to the flowchart shown in Fig.

First, a substrate 40 is prepared (S121 in FIG. 12), and an electrode structure 42 is formed of metal, which is a main material, on the substrate 40. This example is an electrode structure, May be designed with an electrode structure in which a plurality of array types are arranged. The substrate 40 includes a plastic substrate to be applied to a glass substrate or a flexible touch panel. The material of the plastic substrate is selected from the group consisting of PET (polyethylene terephthalate), PEI (polyetherimide), PPSU (polyphenylenesulfonate) Polyphenylenesulfone), PI (polyimide), or a combination thereof.

The electrode structure 42 includes an adhesive layer 401 that is adjacent to the substrate 40 and the adhesive layer 401 is first formed on the surface of the substrate 40 (Fig. 12, S123) Is bonded to the substrate (40) through the adhesive layer (401). The function of the adhesive layer 401 is used to improve the adhesion between the electrode structure and the substrate 40, and this embodiment can enhance the adhesion with a separate adhesive layer; Next, a metal conductive layer 402 is formed on the adhesive layer 401 (Fig. 12, S125). The metal conductive layer 402 is a main conductive structure of the electrode structure 42 and is formed by a method such as electrolysis, sputtering, Can be formed on a specific structure. The material of the metal conductive layer 402 may be a conductive metal material such as silver or copper.

The blackening layer 404 is formed on the metal conductive layer 402 in an electrolytic, sputtering, deposition, or coating manner so as to reduce the color deviation with respect to the screen or the reflection phenomenon occurring in the metal conductive layer 402. [ (FIG. 12, S129). The blackening layer 404 may reduce the color deviation from the screen and prevent reflected light, and may also serve as a protective structure such as structure strengthening and corrosion resistance.

In this embodiment, before forming the blackening layer 404 on the metal conductive layer 402, the light-reducing rough layer 403 may be formed on the surface of the metal conductive layer 402 (Fig. 12, S127) This light-reducing coarse layer 403 is a surface structure formed by performing surface treatment (roughening) on the metal conductive layer 402, for example, etching, surface processing, or the like, as a kind of light- Alternatively, a rough structure layer having a surface structure can be further formed on the metal conductive layer 402 by, for example, electrolysis, sputtering, or deposition. These surface structures can scatter the reflected light formed by the reflection from the metal conductive layer 402, or simultaneously reduce the combined reflected light of both the metal conductive layer 402 and the substrate 40.

The blackening layer 404 may be further formed on the light-reducing coarse layer 403 and the blackening layer 404 may be connected to the surface of the light-reducing coarse layer 403 and may be formed by electrolysis, sputtering, A continuous non-planar structure may be formed on the metal conductive layer 402 by forming one rough blackening layer structure so that the light incident on the metal conductive layer 402 may be diffused or And can prevent the reflected light of the metal. At the same time, it increases the probability of the electron tunneling so as not to lower the conductivity, and furthermore, the bonding strength is stronger than that of the metal conductor, so that it has a protective layer function of corrosion resistance. Since the blackening layer 404 is provided on the outer layer of the entire electrode structure 42, it can assist in defining the shape of the metal electrode.

Further, in one embodiment, the electrode structure 42 contacts other structures at the top and combines with other structures through, for example, an optically clear adhesive (OCA) to form a touch display device, A substrate, a lower film body, a display module, and the like, and when combined with the optical adhesive and the blackening layer 404 of the uppermost layer of the electrode structure 42 of the present example, the characteristics of the blackening layer, To lower the roughness of the rough surface and make the user more comfortable when viewing the touch display device.

Third Embodiment:

5, the electrode structure 52 is formed on the substrate 50, the substrate 50 is prepared as a transparent material such as plastic, glass, or the like, The main structure of the electrode structure 52 includes a first adhesive layer 501 connecting the substrate 50 and the electrode structure 52 and the first adhesive layer 501 is formed between the electrode structure 52 and the substrate 50 Improves bonding properties; A second adhesive layer 502 is further formed on the surface of the first adhesive layer 501. The second adhesive layer 502 is formed on the surface of the substrate 50 and the first adhesive layer 502, 501) can be improved.

A metal conductive layer 503 is formed on the second adhesive layer 502, which is a conductive layer of the electrode structure. The material may be silver, copper, or the like, but is not limited to a specific material in practical implementation. In this example, the surface of the metal conductive layer 503 is etched directly against the metal surface in a manner to be processed to form a light-reducing rough layer 504 having a surface structure; Alternatively, a light-reducing coarse layer 504 having a surface structure may be formed separately by electrolytic, sputtering, or immersion methods. The light-reducing coarse layer 504 may scatter the incident light rays due to the surface structure, and thus does not generate a coherent reflected light shape.

The metal conductive layer 503 described above has a problem that it easily reflects incident light due to its own metal material and is easily oxidized to lower the conductivity. Therefore, a first blackening layer 505 having resistance to corrosion can be formed on the light-reducing coarse layer 504, and the first blackening layer 505 is black or dark in color, effectively reducing the reflected light of the metal , And the first blackening layer can maintain the conductivity of the electrode structure 52 as the material of the metal substrate and can provide better corrosion resistance than the metal conductive layer 503 or other structures It can serve as an auxiliary layer which defines the shape of the electrode structure as a coating structure.

It is possible to form a blackening layer different in the form of a laminate structure, for example, the second blackening layer 506 shown in the drawing, on the first blackening layer 505 in addition to the above-described each layer structure, There is an advantage, and the black chromaticity can be improved, and the coarse structure can further lower the reflectance (reflection light prevention).

In the above-described structure, the electrode structure of the low-reflected light or the non-reflected light can be formed through the optical matching of the structure such as the adhesive layer, the light-reducing rough structure, and the blackening layer, You can comfortably see the display contents of the device.

The blackening layer formed on the electrode structure described above can prevent reflected light from the metal and reduce the color deviation from the screen. The light-reducing rough structure can reduce the reflected light from the inside and the outside, 6, the scattering of the reflected light of the entire structure is increased and the visual comfort is increased when applied to the touch panel.

Fourth Embodiment:

6A, this example forms a light-reducing rough structure 601, 602 using a surface treatment directly on the substrate 60, and the fabrication process is similar to that of the light- Etching or surface processing. More specifically, the light reducing coarse structures 601 and 602 are formed in the manner of chemical etching (sulfuric acid, permanganate, etc.), mechanical and physical or plasma cleaning (e.g., rolling, ion beam, corona, , The materials of the light-reducing rough structures 601 and 602 of this embodiment are the same as those of the substrate material.

When the electrode structure is formed on the surface of the substrate 60, the light-reducing coarse structure formed thereon does not cause the incident light to be reflected in the same coinciding direction, thereby assisting in lowering the reflected light. Thereby directly reducing the light reflected from the light source.

As shown schematically in the surface structure for lowering the reflected light formed on the substrate 60 'shown in FIG. 6B, this example shows that the first light-reducing rough layer 601' is formed on the surface of the substrate 60 ' The objective is to lower the reflected light that can be formed on the surface of the entire substrate 60 ', and the light-reducing coarse layers 601' and 602 'of this example can be formed by increasing the material, for example, , Coating, imprinting, or dipping, to form a light-reducing coarse structure.

In this example, a second light-reducing rough layer 602 'may also be formed on the lower surface of the substrate 60', and the forming method is the same as that of forming the first light-reducing rough layer 601 '. The combination of the first light-reducing coarse layer 601 'and the second light-reducing coarse layer 602' formed on the upper and lower surfaces of the substrate 60 'allows reflected light of a structure in which a light ray is incident from the outside, Module) to effectively lower the visual impact of light rays. The moire interference phenomenon easily caused by the black matrix and the metal electrode arrangement in which the screen backlight passes through the color filter is also generated in the black matrix by the action of the second light- You can reduce the moire problem by destroying the regular backlight. The light-reducing roughened structure formed on the substrate has novel and inventive features that can effectively reduce the thickness of the device and reduce the reflected light of metal and the Moiré interference phenomenon.

2 of the prior art and based on how the incident light is reflected by the substrate surface, the second light-reducing rough layer 602 &apos; of the substrate 60 &apos; (Not shown in Figs. 6A and 6B) provided on the lower surface, when the light beam is incident on the electrode structure of the lower surface, the light-reducing rough structure of the substrate surface is effectively reflected by the metal reflection light of the electrode structure The installation of the second rough layer 602 'on the lower surface can more effectively reduce the reflected light. The method of forming the first light-reducing coarse layer 601 'and the second light-reducing coarse layer 602' of the present example is realized by using materials such as a separately applied ultraviolet adhesive or an organic-inorganic silicone resin curing layer, The light-reducing coarse layer material produced in this manner differs from the substrate material.

(Ra, centerline average roughness) range of the light-reducing rough structures 601 and 602 of the embodiment shown in FIG. 6A and the first light-reducing rough layer 601 'and the second light- Is in the range of 0.001-0.2um, and the preferable range of the illuminance is Ra = 0.02-0.1 um.

Fifth Embodiment:

7A is a schematic diagram of an embodiment in which an electrode structure 72 is formed on a substrate 70 having a surface light reducing rough structure.

The electrode structure 72 is formed on the surface of the substrate 70 in a laminated structure and the main structure of the electrode structure 72 includes a first adhesive layer 721 connected to the substrate 70, On the contacted surface, the light-reducing coarse layer 701 of this example can be formed like the light-reducing coarse structure shown in Fig.

The second adhesive layer 722 shown in the drawing is further formed on the first adhesive layer 721 so that the formed metal conductive layer 723 is bonded and reinforced, An embodiment may be referred to and in order to lower or prevent the reflected light generated in the metal conductive layer 723 the embodiment further includes a light reducing coarse layer 724 in the other electrode structure 72 on the metal conductive layer 723 And a first blackening layer 725 capable of having a corrosion resistance and a blackening effect is adhered to the first blackening layer 725 and another blackening layer is formed on the first blackening layer 725 in order to reduce the effect of color discrepancy The second blackening layer 726 shown in the drawing can be further formed, and it has a function of strengthening the corrosion resistance and the blackening effect.

In the laminated structure of this embodiment, since the light-reducing coarse structure or the blackening structure is formed on the outer surface, it has an effect of lowering or preventing the reflected light of the substrate 70 or the metal conductive layer 723, .

Sixth Embodiment:

FIG. 7B shows that a light-reducing rough structure (e.g., 724 in FIG. 7A) in the fabrication process can be implemented simultaneously on the substrate and the electrode in the last fabrication procedure. When the final processing procedure is carried out, the embodiment can realize a light-reducing rough structure by using a material such as an ultraviolet adhesive or an organic-inorganic silicone resin hardened layer separately coated, and the material of the light- And the material of the substrate. The processing method can form the present light-reducing coarse structure by, for example, electrolysis, sputtering, coating, imprinting or dipping.

7B, the electrode structure 72 'formed on the substrate 70' does not show the light-reducing rough layer 724 formed on the metal conductive layer 723 as shown in FIG. 7A, The first blackening layer 725 'is formed directly on the metal conductive layer 723, or the second blackening layer 726' is formed on the metal conductive layer 723 without forming the light-reducing rough layer (e.g., 701 in FIG. 7A) And then form a light reducing roughened structure 727 on the substrate 70 'and the electrode structure 72' simultaneously during the final fabrication process.

7A or 7B, the first adhesive layer 721 and / or the second adhesive layer 722 may be a polymer, an oxide, a metal material, or a combination of these materials. More specifically, the polymer material included in the first adhesive layer 721 helps improve adhesion between the first adhesive layer 721 and the substrate 70. [ The oxide material included in the first adhesive layer 721 and / or the second adhesive layer 722 is such that the adhesive layer has antireflection, interference prevention, rainbow pattern prevention, abrasion resistance, and scratch resistance. The metal material included in the first adhesive layer 721 improves the adhesive function of the first adhesive layer 721 and the second adhesive layer 722.

In the material for forming each layer in the laminated structure, the polymer material includes acrylic, PET, PEI, PPSU, PI, PEDOT, polyaniline, polypyrrole or a combination of composites thereof. The oxide may be an amorphous or polycrystalline oxide film or powder structure. Among them, the composition of the oxide may be titanium oxide, tantalum oxide, silicon oxide, aluminum oxide or a composite material combination thereof. The metal can include copper, silver, aluminum, molybdenum, nickel, chromium, tungsten, titanium, silicon, zinc, tin, iron and other alloys or combinations of composites thereof. A composite material of a polymer, a metal and an oxide, or a combination of two or three, for example, a combination of a metal and an oxide, a combination of a polymer and a metal, a combination of a polymer and an oxide, or a combination of a metal and an oxide and a polymer. If a composite material is used, the occupation rate of the polymer is 10-90%, the occupation rate of the oxide is 10-90%, and the occupation rate of the metal is 10-90%. The oxide may also have a multilayer structure.

According to one embodiment, the thickness of the titanium oxide described above may be about 900 nm, and the thickness of silicon oxide may be about 100 nm. The thickness of the first adhesive layer 721 and / or the second adhesive layer 722 ranges from 0.001 um to 1 um; The reflectance of the first adhesive layer and / or the second adhesive layer 722, 721 should be in the range of 1% to 50%, preferably less than 30%. In addition, the first adhesive layer 721 and / or the second adhesive layer 722 can also be made rough by the processing method, and the effect of removing reflected light can be achieved. The method of forming the first adhesive layer 721 and / or the second adhesive layer 722 includes (1) increasing the energy of the first adhesive layer sputtering to enter the material of the adhesive layer into the substrate material; (2) adding a colored polymer such as polyaniline to the adhesive layer; Or (3) a porous structure by etching the adhesive layer material.

The metal conductive layer 723 material may be a combination of copper, gold, silver, aluminum, tungsten, iron, nickel, chromium, titanium, molybdenum, indium, tin or a combination thereof, good.

In order to increase the adhesion and conductivity of the electrode structure 72, when the metal conductive layer 723 is pure metal, the adjacent second adhesive layer 722 may contain a content exceeding 50% of the pure metal, The adhesive layer 721 is a layered structure that can contain a content lower than 50% of the pure metal. For example, when the metal conductive layer 723 is pure copper, the first adhesive layer 721 may be a nickel-copper-chromium-iron alloy and may have a composition of nickel: copper: chromium: iron = 60: 30: 10: 0 or nickel: copper: chromium: iron = 80: 10: 5: 5. The first adhesive layer 721 may be a nickel-tungsten alloy, and its composition is nickel: tungsten = 50:50. The first adhesive layer 721 may additionally include silicon and phosphorus. The second adhesive layer 722 can be a copper-nickel-chromium alloy and has a composition of copper: nickel: chromium = 60:30:10. Or a copper-nickel-tungsten alloy, the composition of which is copper: nickel: tungsten = 60:20:20; The second adhesive layer 722 may also contain silicon and phosphorus.

The light-reducing coarse layer 724 disposed in the electrode structure 72 can be roughened using a light mechanical coarse structure, using a physical mechanical (rolling, plasma etching) or chemical etching method, The material is the same material as that of the metal conductive layer 723.

Based on the structural design of the light-reducing coarse layer (e.g., 724 in FIG. 7A), the structure may be further extended to increase the light-reducing coarse layer 724 to cover over the metal conductive layer 723, The material of the coarse layer 724 may be different from the metal conductive layer 723. For example, (1) the coating film condition is changed to dry coating film: sputtering, vapor deposition; Or wet coatings: plated, chemically plated, etc., and plated with a discontinuous island-like distribution of light-reducing coarse layer 724 to form a coarse surface or porous structure; Or (2) first, the light-reducing coarse layer 724 material is plated in a flat continuous structure and roughened by physical mechanical (rolling, plasma etching) or chemical etching to enhance the surface roughness in a destructive manner. The material of the light-reducing coarse layer 724 fabricated using the growth method may be the same as the metal conductive layer 723 as a polymer, an oxide and a metal; Or the first blackening layer 725.

The light-reducing coarse layer 724 may affect the surface roughness of the electrode structure 72 and may have the ability to prevent reflected light and increase the photo or thermotropic resist deposited on the surface of the electrode structure 72, Since it is not necessary to separately add an anti-glare film, the cost can be reduced and at the same time the fine line etching is not affected. The preferable surface roughness range of the light-reducing coarse layer 724 is Ra = 0.001 um to 0.2 um, and the best roughness Ra = 0.02 um to 0.1 um. The reflected optical haze should be less than two.

The first and / or second blackening layers 725 and 726 materials described above may be a combination of copper, silver, aluminum, molybdenum, nickel, chromium, tungsten, titanium, silicon, zinc, tin, . The thickness of the first blackening layer 725 and / or the second blackening layer 726 is preferably in the range of 0.001 um to 1 um; The reflectance of the first blackening layer 725 and / or the second blackening layer 726 may range from 1% to 50%, preferably less than 30%.

The second blackening layer 726 described above is another formed blackening layer and can coat the first blackening layer 725 to improve the corrosion resistance and blackening ability and increase the environmental adaptability of the overall structure, (725) to adjust the color chromaticity and light reflection ability of the entire electrode. The second blackening layer 726 material may be an oxide, a polymer, carbon and mixtures thereof. The oxide may be silicon oxide, titanium oxide, alumina and mixtures thereof. The polymer may be acrylic (acrylic acid), an alkylbenzimidazole (alkylbenzene) mixture, an alkylbenzene compound, PET or a colored organic material: PEDOT, polyaniline or a mixture thereof.

In the mixture of the second blackening layer 726, the ratio of the polymer is 10-90%, and the ratio of the oxide is 10-90%. The thickness of the second blackening layer 726 is preferably in the range of 0.001 um to 1 um; The reflectance of the second blackening layer 726 is in the range of 1% to 50%, preferably less than 30%. In addition, the total reflectance generated in the first blackening layer 725 and the second blackening layer 726 is preferably less than 30%. For example, when the present apparatus is applied to a display, if the screen backlight is turned off, its reflectance is lower than 30%, the a / -a axis of chromaticity coordinates is lower than -2, b / -b axis) is lower than -4. In particular, the chromaticity of the screen on which the polarizing plate is projected is further deflected to the south green, and the b value of the screen on which the polarizing plate is mounted is about -7. Therefore, the first blackening layer 725 simultaneously adjusts the metal fine line and the metal color of the metal fine line so that the metal fine line and the color thereof (for example, the reflectance of the pure copper base material> 50%, L> 90%, a <0.1, b> 2) can approach the color of the screen black matrix (BM), thereby reducing the contrast chromatic aberration. If the B value is greater than 1, or if the reflectance is greater than 50%, the human eye will easily observe the reflected metallic light on the yellow. The chromaticity of the first and second blackening layers 725 and 726 itself may vary due to material thickness. The second blackening layer 726 can adjust the chromaticity of the coated first blackening layer 725 to approach the color of the black matrix of the screen further and at the same time to prevent color deviation, prevent reflection, prevent moire interference, , Abrasion resistance, and scratch resistance.

In addition, although the description in the specification provides a specific embodiment for lowering the reflected light by forming roughness in the electrode structure, the present invention is not limited by the various embodiments described in the specification.

Example 7:

In another embodiment, as shown in Fig. 8, this example is a schematic diagram of an embodiment of applying the substrate and electrode structure of the present invention to a touch panel.

In addition to the embodiment in which a light-reducing rough structure is formed on one surface of a substrate, this example shows that both the upper and lower surfaces of the display substrate 80 have a light reducing rough structure, for example, a first light- Forming a coarse layer 802 and may be formed by a method such as chemical etching (sulfuric acid, permanganate, etc.), mechanical physics or plasma cleaning (e.g., rolling, ion beam, corona, atmospheric plasma).

The first electrode structure 82 formed above the first light-reducing coarse layer 801 on the substrate 80 and the second electrode structure 84 formed below may have the same structure, 7B can be referred to. The first electrode structure 82 and the second electrode structure 84 may have a structure capable of preventing color deviation, preventing reflection, preventing Moire interference, preventing iridescence, preventing wear and scratches, , A light reduction rough structure, and the like, and the embodiment can refer to the description of Fig. 7A or Fig. 7B. A first light-reducing coarse layer 801 is formed on the surface of the substrate 80 facing outward to prevent reflected light from the substrate 80 and a second light-reducing coarse layer 802 is formed on the second electrode structure 84 Since the formed metal semi-scattered light can be lowered or prevented, it is possible to increase the flatness of the human eye because the metallic reflected light is significantly lowered from the outside (upper part of the drawing) to improve the visual effect, And a function of reducing the Moire interference shape.

 When a touch panel device is formed by the substrate 80 and the electrode structures 82 and 84 and the touch display panel device is combined with this device and other devices, the optical adhesives 811 and 812 ) Can be used as an adhesive. For example, the touch panel device formed of the substrate 80 and the electrode structures 82 and 84 is combined with the upper optical component, for example, the transparent substrate 803 and the related optical element by the optical adhesive 811, The optical adhesive 812 and the liquid crystal display module 804 (in this example, on the lower side) can be combined. When the light reducing roughened structure is formed on the surface of the combination of the substrate 80 and the electrode structures 82 and 84 as described above and the optical adhesive 811 and 812 are filled with the optical components 811 and 812, , And 812 can fill in gaps in the surface roughened structure, thereby lowering the haze of the light-transmitting region due to roughness and increasing the light transmittance of the light-transmitting region.

However, after the optical adhesives 811 and 812 are attached, the roughness of the first light-reducing rough layer 801 and the second light-reducing rough layer 802 formed on the surface of the substrate 80 is lower than that of the optical adhesives 811 and 812, The human eye can lower the haze sensitivity to the light transmitting region. In addition, since the material of the optical adhesives 811 and 812 is close to the substrate 80 and the difference in the refractive index is smaller, the rough surface of the touch panel device is formed on a very large surface and only the light transmittance of the substrate 80 light- In addition, since the color of the anti-corrosion black layer is further deflected to the chromatic black or the chromaticity similar to that of the black matrix of the screen, the whitening effect caused by the haze becomes unfavorable and does not affect the light reduction rough layer effect of the electrode, It shields the metal grid and improves the comfort of the human eye.

It should be noted that, unlike a method in which a thin film material, that is, an antireflection film having a relatively low refractive index, is plated on a substrate and the substrate transmittance is improved, in the application using the optical adhesive according to the present invention, For example, after roughening the surface of PET, besides covering the rough structure of the surface by covering the optical adhesive, the increased haze can be lowered by roughening. For example, the refractive index of both the optical adhesive and the panel device glass may be lower than that of PET, so that the transmittance can be improved. The data of each structure described above, for example, refractive index of surface glass: 1.53; Optical adhesive refractive index: 1.46-1.47, optical grade PET refractive index: 1.62.

Embodiments of the electrode structure may not be limited to the above-described drawings, and each drawing shows another electrode structure embodiment, in which the material of the adhesive layer, the metal conductive layer, the light-reducing coarse layer and the blackening layer, The relationship between the method and the laminate structure is the same as each of the above-described embodiments, and is not described here.

In the embodiment shown in FIG. 9, there is a light-reducing rough structure that lowers the reflected light on the surface of the substrate 90. Like the light-reducing coarse layer 901 shown in the drawing, an electrode structure is formed on the upper portion, 7A, 7B and 8, which are described above, and in a practical implementation is not limited to the above-described structure, of which the metal conductive layer 923 is directly etched or processed The first blackening layer 924 and the second blackening layer 925 both form a light-reducing coarse structure and form a light-reducing coarse layer, and the structure to be connected forms a rough surface. For example, And forms a coarse surface along the light-reducing rough structure of the light source 923.

The first blackening layer 924 'formed on the metal conductive layer 923' in the electrode structure formed on the light-reducing coarse layer 901 on the surface of the substrate 90, as in the electrode structure embodiment shown in FIG. 10 Directly etched or worked to form a blackened layer having a rough surface, that is, the above-described light reducing and roughening structure is directly formed by processing the blackening layer. The first blackening layer 924 'is formed on the metal conductive layer 923' by an electrolytic, sputtering, dipping or coating method. This rough surface is formed by etching or machining on the surface of a blackening layer 924 ', and the first blackening layer 924' having the rough surface is reflected by the metal conductive layer 923 ' Scattering the reflected light, and further reducing the amount of reflected light.

Subsequently, another blackening layer, for example, a second blackening layer 925 'as shown, can be further formed on the first blackening layer 924' having a rough surface, and likewise the surface structure of the first blackening layer 924 ' To form a rough surface.

11, the first blackening layer 924 &quot; does not change over the metal conductive layer 923 &quot; in the electrode structure, and the second blackening layer 925 &quot; And the surface is roughened to form a rough surface. The second blackening layer 925 &quot; having the rough surface is formed by being connected to the surface of the first blackening layer 924 &quot; to reflect the reflected light formed by the metal conductive layer 923 &quot; And reduces the amount of reflected light.

In the step of producing the two layers of blackening, the first blackening layer 924 &quot; is formed on the metal conductive layer 923 &quot; by electrolytic, sputtering, dipping or coating methods; The second blackening layer 925 &quot; is formed on the first blackening layer 924 &quot; by electrolytic, sputtering, deposition or coating methods, both of which are similar fabrication methods.

In the embodiment shown in Fig. 11, the material of each of the electrode structures and the composition thereof can be referred to the description of each of the embodiments, and the condition of the material combination, thickness, and reflectance of the first or second blackening layer The contents described in each embodiment can be referred to.

Thus, in the touch panel device proposed by the present invention, unlike the conventional electrode lattice touch panel in which a single layer of blackening layer is plated on the copper layer to lower the reflected metal light, By using the structure and material design, it is possible to eliminate the problem of the reflected light of the metal and plastic substrates, more effectively reduce the thickness of the touch panel, and not affect the haze of the light-transmitting region; At the same time, it does not affect the conductivity of the copper conductive layer, has excellent weatherability, and realizes excellent lifetime in an environment of high temperature salinity.

The foregoing description is only a preferred embodiment of the present invention, and all of the equivalent changes and modifications made in the scope of the present invention belong to the scope of the present invention.

10: substrate 101, 102: electrode structure
11, 13, 15: optical adhesive 12: anti-glare film
14: upper substrate 16: liquid crystal display module
21: plastic substrate 23: first electrode
25: first blackening layer 29: second electrode
27: second blackening layer 201, 203: incident light
202, 204, 205: Reflected light
30: substrate 32: electrode structure
301: metal conductive layer 302: light-reducing rough layer
303: Blackening layer
40: substrate 401: adhesive layer
42: electrode structure 402: metal conductive layer
403: light reduction coarse layer 404: blackening layer
52: electrode structure 50: substrate
501: first adhesive layer 502: second adhesive layer
503: metal conductive layer 504: light-reducing rough layer
505: first blackening layer 506: second blackening layer
60, 60 ': substrate 601': first light-reducing rough layer
602 ': second light-reducing coarse layer 601, 602: light-reducing coarse structure
70, 70 ': substrate 72, 72': electrode structure
701, 724: light-reducing rough layer 721: first adhesive layer
722: second adhesive layer 723: metal conductive layer
725, 725 ': first blackening layer 726, 726': second blackening layer
727: Light Reduction Coarse Structure
80: substrate 801: first light-reducing rough layer
802: second light-reducing rough layer 82: first electrode structure
84: Second electrode structure 811, 812: Optical adhesive
803: transparent substrate 804: liquid crystal display module
90: substrate 901: light-reducing rough layer
923, 923 ', 923'': metal conductive layer
924, 924 ', 924 &quot;: first blackening layer
925, 925 ', 925'': The second blackening layer
S121 to S129: Step of fabricating the electrode structure

Claims (20)

In the electrode structure,
A metal conductive layer which is a conductive structure of the electrode structure;
A first blackening layer that absorbs light rays incident on the electrode structure, removes reflected light generated from the metal conductive layer, and reduces color deviation from the screen;
A second blackening layer formed on the first blackening layer, the second blackening layer improving the resistance to corrosion, reducing color discrepancies with the screen and increasing the blackening ability; And
And a light-reducing rough structure formed on the electrode structure and formed on the metal conductive layer or the first blackening layer,
Wherein the light-reducing rough structure scatters a light beam incident on the electrode structure or a reflection light generated in the metal conductive layer, and simultaneously prevents Moire interference,
Wherein the light-reducing coarse structure is formed of a light-reducing coarse layer having a surface structure on the surface of the first blackening layer, the light-reducing coarse structure material being different from the first blackening layer, and the light- 0.001um to 0.2um. The method according to claim 1,
Wherein the light-reducing rough structure is formed after the surface of the metal conductive layer is etched or processed when the light reducing rough structure is formed by connecting on the metal conductive layer, Same, electrode structure. The method according to claim 1,
Wherein when the light reducing rough structure is formed by connecting on the metal conductive layer, the light reducing rough structure forms a light reducing rough layer having a surface structure on the metal conductive layer, An electrode structure, different from the metal conductive layer. The method according to claim 1,
Wherein the light reducing rough structure is formed after etching or processing the surface of the first blackening layer when the light reducing rough structure is formed on the surface of the first blackening layer, Electrode structure, such as a layer. The method according to claim 1,
Wherein the first blackening layer or the second blackening layer forms a rough surface along the light reducing rough structure. The method of claim 5,
Wherein the material of the first blackening layer or the second blackening layer is selected from the group consisting of copper, silver, aluminum, molybdenum, nickel, chromium, tungsten, titanium, silicon, zinc, tin, iron or combinations thereof; The thickness of the first blackening layer or the second blackening layer is from 0.001 탆 to 1 탆; And the reflectance of the first blackening layer or the second blackening layer is 1% to 50%. The method according to claim 1,
Wherein the electrode structure is formed on a substrate, a light reducing rough structure is formed on the substrate surface, the light reducing rough structure is formed after etching or processing the substrate surface, and the light reducing rough structure material is formed on the substrate Such as the electrode structure. The method according to claim 1,
Wherein the electrode structure is formed on a substrate and forms a light reducing rough structure as a light reducing coarse layer having a surface structure on the substrate, wherein the light reducing rough structure material is different from the substrate. The method according to claim 1,
And an adhesive layer formed between the metal conductive layer and the substrate, wherein the adhesive layer is used to improve adhesion between the electrode structure and the substrate when the electrode structure is bonded to the substrate. The method of claim 9,
Further comprising a second adhesive layer between the adhesive layer and the metal conductive layer to improve the adhesiveness therebetween. The method of claim 10,
Wherein the adhesive layer or the second adhesive layer is a polymer, an oxide, a metal material, or a combination of materials thereof; The thickness of the adhesive layer or the second adhesive layer is in the range of 0.001 탆 to 1 탆; And the reflectance range of the adhesive layer or the second adhesive layer is 1% to 50%. In the panel device,
A substrate having at least one surface; And
And one or more electrode structures formed on a surface of the substrate,
Among them, the electrode structure
A metal conductive layer which is a conductive structure of the electrode structure;
A first blackening layer that absorbs light rays incident on the electrode structure, removes reflected light generated from the metal conductive layer, and reduces color deviation from the screen;
A second blackening layer formed on the first blackening layer, the second blackening layer improving the resistance to corrosion, reducing color discrepancies with the screen and increasing the blackening ability; And
And a light-reducing rough structure formed on the electrode structure and formed on the metal conductive layer or the first blackening layer,
Wherein the light reducing rough structure scatters the light incident on the electrode structure and the light reflected from the metal conductive layer,
Wherein the light-reducing coarse structure is formed of a light-reducing coarse layer having a surface structure on the surface of the first blackening layer, the light-reducing coarse structure material being different from the first blackening layer, and the light- 0.001um to 0.2um. The method of claim 12,
Wherein a light-reducing rough structure is formed on the surface of the substrate. The method of claim 12,
Further comprising an optical adhesive to fill the panel device when the substrate having the one or more electrode structures engages other parts in the panel device. 15. The method of claim 14,
Wherein the optical adhesive is used to fill a gap between the substrate and the light reducing coarse structure of the one or more electrode structures to lower the haze by the coarse structure or to increase the light transmittance of the light transmitting region. In the panel device,
A substrate having at least one surface; And
And one or more electrode structures formed on a surface of the substrate,
Among them, the electrode structure
A metal conductive layer which is a conductive structure of the electrode structure;
A first blackening layer that absorbs light rays incident on the electrode structure, removes reflected light generated from the metal conductive layer, and reduces color deviation from the screen;
A second blackening layer formed on the first blackening layer, the second blackening layer improving the resistance to corrosion, reducing color discrepancies with the screen and increasing the blackening ability; And
A light-reducing coarse structure formed on the surface of the substrate and the one or more electrode structures,
Wherein the light-reducing coarse structure scatters the light incident on the electrode structure and the substrate, and the reflected light,
Wherein the light-reducing coarse structure is formed of a light-reducing coarse layer having a surface structure on the surface of the first blackening layer, the light-reducing coarse structure material being different from the first blackening layer, and the light- 0.001um to 0.2um. 18. The method of claim 16,
Wherein the electrode structure or the light-reducing rough structure formed on the substrate is formed by coating an ultraviolet adhesive or an organic-inorganic silicon resin cured layer. 18. The method of claim 16,
Wherein the electrode structure or the light-reducing rough structure formed on the substrate is formed by a method of electrolysis, sputtering, coating, imprinting or deposition. delete delete

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