CN214152473U - Double-sided conductive film and touch screen - Google Patents

Abstract

The embodiment of the application discloses a double-sided conductive film and a touch screen, wherein the conductive film comprises a transparent substrate, a low-resistance conductive layer, a CU layer and a protective layer, wherein the low-resistance conductive layer, the CU layer and the protective layer are sequentially stacked on two sides of the transparent substrate; the protective layer is a CU alloy layer or an MO alloy layer; the low-resistance conducting layer is used for conducting electricity, and the resistance of the low-resistance conducting layer is not more than 100 ohms. According to the technical scheme, the CU is adopted to replace silver paste, the CU alloy is used as a protective layer, and through experimental verification, even if the line width is larger than the line distance and is 5um is larger than 5um, the conductivity of the etched CU alloy can be guaranteed.

Description

Double-sided conductive film and touch screen

Technical Field

The application relates to the field of optical films, in particular to a double-sided conductive film and a touch screen.

Background

The silver paste that adopts the printing in present electric capacity touch screen walks the line more, and its structure is shown as fig. 1 mostly, includes substrate layer (PET layer), locates the conducting layer (ITO) of PET both sides and locates the Ag thick liquid layer in the conducting layer outside. And the Ag paste layer is coated and printed on the conductive layer, and then silver paste routing is formed by etching. And the exposed area after etching is used as the display area of the touch screen. The silver paste routing part forms a common frame after covering treatment, such as a black frame of two layers of a mobile phone.

Obviously, in order to enlarge the display area, the narrower the trace portion is, the better, but at the same time, the conductivity of the trace is ensured. Under the silver paste coating mode, the silver paste is broken due to over-narrow coating, and the conductivity is damaged. Therefore, the line width X-ray distance of the current silver paste is generally not less than 100um multiplied by 100 um. How to narrow the line width of the trace on the premise of ensuring the conductive performance to reduce the line width of the frame and expand the display area is a problem to be solved at present.

SUMMERY OF THE UTILITY MODEL

The application provides a double-sided conductive film and a touch screen to solve the problems in the prior art.

The application provides the following scheme:

on one hand, the double-sided conductive film is provided, and comprises a transparent substrate, a low-resistance conductive layer, a Cu layer and a protective layer which are sequentially stacked on two sides of the transparent substrate;

the protective layer is a Cu alloy layer or a Mo alloy layer;

the low-resistance conducting layer is used for conducting electricity, and the resistance of the low-resistance conducting layer is not more than 100 ohms.

Preferably, the Cu alloy layer contains Ni, and Ni accounts for 10 to 90 wt% of the Cu alloy layer.

Preferably, the protective layer is a blackened layer.

Preferably, the single-sided stress of the double-sided conductive film is 1-3N/m 2.

Preferably, the double-sided conductive film further includes an IM layer respectively disposed between the transparent substrate and each of the low-resistance conductive layers; the IM layer comprises an organic material layer and an inorganic material layer which are sequentially laminated on the transparent substrate.

Preferably, the low-resistance conductive layer comprises a first metal doped layer and a first transparent conductive material layer; the metal doped layer is a doped layer of metal and nitride metal and/or metal and oxide metal.

Preferably, the low-resistance conducting layer comprises a second metal doped layer, a second transparent conducting material layer, a third metal doped layer and a third transparent conducting material layer;

the second metal doped layer and the third metal doped layer are both doped layers of metal and nitrogen/oxide metal.

Preferably, the low-resistance conductive layer includes a first metal layer, a fourth transparent conductive material layer, a second metal layer, and a fourth transparent conductive material layer.

On the other hand still provides a touch screen, the touch screen is formed through the laser etching to foretell double-sided conductive film, the line width x line distance that the Cu layer and the protective layer formed after the etching is 5um x 5um-100um x 100 um.

Preferably, the protective layer is a blackening layer, and the width of the frame of the touch screen is 0.5mm-2 mm.

According to the specific embodiments provided herein, the present application discloses the following technical effects:

according to the technical scheme, silver paste is replaced by Cu, the Cu alloy is used as a protective layer, and tests prove that even if the line width X line distance is 5um multiplied by 5um after etching, the conductivity of the copper-clad copper can be guaranteed.

Furthermore, the protective layer can be a blackening layer, so that other black covering layers do not need to be added outside the protective layer, and the distance between the final frames is narrower.

Furthermore, the integral reflectivity of the IM layer is reduced by arranging the two IM layers, so that the IM layer can be matched with the low reflectivity of the conducting layer, and the integral chromatic aberration of the transparent conducting film is reduced.

Furthermore, the metal doping layer has better conductivity at a lower thickness of, for example, less than 10nm by utilizing the better continuous film layer characteristic of the metal doping layer in which the metal and the oxynitride metal coexist, so that the conductivity is improved under the condition of the same thickness compared with the metal layer.

In another scheme, the metal layer/metal doped layer is arranged in two layers, so that the refractive index is improved under the condition that the total thickness of the corresponding layer in the prior art is the same, the refractive index matching with high-refractive-index glass, OCA glue and the like in the touch screen is further realized, and the light transmittance is improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a structure view of a conductive film in the prior art;

fig. 2 is a structural view of a transparent conductive film provided in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments that can be derived from the embodiments given herein by a person of ordinary skill in the art are intended to be within the scope of the present disclosure.

The application aims at providing a two-sided conductive film of new construction, utilizes Cu and metal alloy to replace silver thick liquid as walking the line to use resistance to be less than 100 ohmic low resistance rete, realize two-sided low resistance conductive film, and can realize under 5 um's the linewidth, electric conductive property still obtains guaranteeing.

As shown in fig. 2, the structure diagram of the double-sided conductive film provided by the present invention specifically includes: the low-resistance conductive layer comprises a transparent base material 21, and a low-resistance conductive layer 22, a Cu layer 23 and a protective layer 24 which are sequentially stacked on two sides of the transparent base material 21; the protective layer 24 is a Cu alloy layer or a Mo alloy; the low-resistance conductive layer 22 is used for conduction, and the resistance of the low-resistance conductive layer 22 is not more than 100 ohms.

The thickness of the Cu layer may be preferably 100-300nm, and the resistance is preferably 0.1-0.3 ohm.

The protective layer is preferably a Cu alloy or a Mo alloy. Such as CuNi (Ni accounts for 10-90 wt%), CuNiTi (Ni accounts for 10-50 wt%, Ti accounts for 1-10 wt%), CuNiOx (Ni accounts for 10-90 wt%), MoNbOx (Nb accounts for 0-10 wt%), etc. The thickness thereof is preferably 5 to 100 nm.

Wherein the Cu layer and the protective layer may be provided on the low resistance conductive layer by sputtering.

The conductive film is formed by plating, and the double-sided conductive film requires double-sided plating. In the current double-sided coating process, the substrate and the coated film layer generate stress during the first coating. Although the temperature of the water cooling equipment is reduced in the coating process, the temperature reduction speed is limited, so that the stress cannot be released during the second coating, and the heat cannot be released in the coating process, so that the coating speed is limited in the secondary coating process. The coating speeds of the two coating processes are different, which can lead to the appearance of the two surface films being different.

Therefore, in the application, the temperature of the coating process is reduced by adopting a gas cooling mode, and helium or argon and other inert gases can be selected for gas cooling. Of course, the temperature can be reduced by both water cooling and air cooling.

Through the air cooling mode, the heat in the process of coating films for two times can be rapidly reduced, so that the stress generated by the first coating film is reduced, the heat emission in the process of coating films for two times is also ensured, and the consistency of the appearance of the two coating films is further realized on the premise of ensuring the coating speed.

In the air cooling mode, the stress generated by the first film plating is 1-3N/m 2.

In order to realize low-resistance performance, the low-resistance conducting layer in the application adopts a metal layer doped layer, and specifically comprises a first metal doped layer and a first transparent conducting material layer; the metal doped layer is a doped layer of metal and nitride metal and/or metal and oxide metal.

The doped layer in which metal and nitrogen/oxide metal coexist has a characteristic that even in the case of a thin thickness, for example, less than 10nm, it is a continuous film layer, and the conductivity is greatly improved compared with a pure metal layer of the same thickness. In an actual arrangement, the metal doped layer may be set to 10nm or less.

The metal doped layer can be formed by introducing a small amount of O2 and/or N2 during the metal target coating process, so that the metal and the oxidized/nitrided metal coexist. The metal is typically Ag, Cu, Al, Mo, Ag alloy, Cu alloy, Al alloy, Mo alloy, etc. The atomic percentage of oxygen or nitrogen atoms in the metal doped layer is 1.5at percent to 5.5at percent. The atomic percent of oxygen or nitrogen atoms can be controlled by controlling the amount of O2 and/or N2 introduced. In the preferred embodiment, the metal Ag is connected with O2, and the metal Cu is connected with N2.

In order to ensure the conductivity of the conductive film, the metal doped layer needs to adopt a continuous film layer structure, and preferably, the thickness of each layer of the metal doped layer is more than 10 nm. Wherein the material of the metal doped layer may preferably be silver.

In a preferred embodiment, the low-resistance conductive layer comprises a second metal doped layer, a second transparent conductive material layer, a third metal doped layer and a third transparent material layer which are sequentially stacked. The second metal doped layer and the third metal doped layer are both doped layers of metal and nitrogen/oxide metal.

In the prior art, the refractive index of the glass and the OCA adhesive of the touch screen is high, and is about 1.5. However, the overall refractive index of the current low-resistance conductive layer is low, approximately 0.8-1.4, and cannot be matched with the low-resistance conductive layer, so that chromatic aberration is caused. Therefore, the metal doped layer is divided into two layers, and compared with the arrangement of a single metal doped layer, the refractive index of the whole conductive layer can be improved under the condition that the total thickness of the metal doped layer is the same. If the single metal doping layer is 26nm, the single metal doping layer can be divided into two 13nm metal doping layers; it can also be divided into two layers with different thicknesses, such as 11nm and 15 nm.

Through the arrangement of the two metal doped layers, the overall refractive index of the conducting layer can reach 1.4-1.5, so that the refractive index matching with glass and OCA glue can be realized, and the light transmittance of the overall touch screen product is improved.

The above idea of layered arrangement can also be applied to the condition of conducting through a simple metal layer, and at this time, the conducting layer includes a first metal layer, a fourth transparent conducting material layer, a second metal layer, and a fifth transparent material layer which are sequentially stacked.

The metal layer is divided into two layers, and compared with the arrangement of a single metal layer, the overall refractive index of the conductive layer can be improved under the condition that the overall thickness of the metal layer is the same. If the single metal layer is 30nm in the prior art, the single metal layer can be divided into two 15nm metal layers in the application; or can be divided into two layers with different thicknesses, such as 18nm, 12nm and the like. In order to ensure the conductivity of the conductive film, the metal layer needs to adopt a continuous film structure, and preferably, the thickness of each layer of the metal layer is more than 10 nm. Wherein the material of the metal layer may preferably be silver.

The metal layer is divided into two layers, and compared with the arrangement of a single metal layer, the overall refractive index of the conductive layer can be improved under the condition that the overall thickness of the metal layer is the same. If the single metal layer is 30nm in the prior art, the single metal layer can be divided into two 15nm metal layers in the application; or can be divided into two layers with different thicknesses, such as 18nm, 12nm and the like.

In order to ensure the conductivity of the conductive film, the metal layer needs to adopt a continuous film structure, and preferably, the thickness of each layer of the metal layer is more than 10 nm. Wherein the material of the metal layer may preferably be silver.

In a more preferred embodiment, the double-sided conductive film further includes an IM layer respectively disposed between the transparent substrate and each of the low-resistance conductive layers; the IM layer comprises an organic material layer and an inorganic material layer which are sequentially laminated on the transparent substrate.

The inorganic material layer is in contact with the low-resistance conductive layer in consideration of not affecting the conductivity of the low-resistance conductive layer.

Wherein the organic material layer can be made of C \ H \ O resin with high refractive index of 1.6-1.7, wherein metal elements such as Si, Zr, Ti and the like are doped; the thickness can be set as desired, preferably 0.5-5 um.

The inorganic material layer may be a single layer or may be a plurality of matching layers having different refractive indices.

If the insulation sheet resistance is a single layer, a non-conductive metal material with an insulation sheet resistance of more than 10 x 8 Ω/□ can be used, for example: ti, In, Sn, InSn alloy (In doping weight percentage is 0-50 percent), SiAl alloy (Al doping weight percentage is 0-50 percent), and the thickness can be set according to the requirement, and is preferably 0.5-80 nm.

The inorganic material layer is formed by combining at least one layer of low refractive index material and at least one layer of high refractive index material, and the insulation sheet resistance of the inorganic material layer is more than 10 x 8 omega/□. Wherein the low refractive index material can be metal oxide with a refractive index of 1.2-1.7, non-metal oxide, sulfide, fluoride, carbide, such as SiO2, Al2O3, MgF, MgS, SiC, etc., and the thickness can be set to 10-500 nm; the high-refractive-index material can be metal oxide, nitride, sulfide with a refractive index of 1.8-2.4, or a dopant thereof (the doped material comprises one or more of Al, Ga, Zr, B, Y, Mo, Sn and the like), such as TiO2, SnO2, ZnO, Nb2O5, Ta2O5, Si3N4, ZnS, the dopant comprises AZO, GZO, YZO and the like, and the thickness can be set to be 2-200 nm.

In the actual manufacturing process, the first IM layer is preferably coated, and the second IM layer is preferably sputtered, which takes into account that although the sputtering method has better adhesion, the sputtered layer has color difference. The coating mode has general adhesive force but small color difference, so the IM layer can be arranged by adopting the combination of coating and sputtering to meet the comprehensive requirements of adhesive force and color difference.

In a preferred embodiment, a greater number of IM layers may be provided as desired and will not be described in detail herein.

The provision of at least two IM layers allows the refractive index of the IM layer as a whole to be made low to match the low-reflectance conductive layer in the low-resistance conductive film. According to low resistance techniques, the conductive layer may have a resistance of less than 100 ohms, typically 20-25 ohms, and a reflectivity of 5.8. Correspondingly, in the present application, the overall reflectivity of at least two IM layers is 5.6.

The transparent substrate may be a flexible substrate such as transparent organic polymers PET, TAC, COP, PEN, CPI, PI. Preferably, PET is selected.

The transparent conductive material layer may be a metal oxide, such as In2O3, SnO2, ZnO, ITO (Sn2O doped at 0-50 wt%), IZO (ZnO doped at 0-50 wt%), AZO (Al2O3 doped at 0-50 wt%); ITiTO (TiO2 doped 0-10% by weight); ITZO (0-10% by weight of doped TIO2, 0-40% by weight of doped ZnO), and FTO (0-10% by weight of doped F).

Another embodiment of this application discloses a touch screen, the touch screen is through handling the etching to above-mentioned double-sided conductive film and forming, the Cu layer reaches the linewidth that the protective layer formed after the etching is 5um, is less than the linewidth that adopts silver thick liquid to walk the line far away. The frame linewidth of the touch screen can be within 2 mm.

In order to further realize the narrow frame, the protective layer in the application is a blackening layer for blackening the copper layer. The emissivity is typically within 20. At the moment, the frame line width of the touch screen can reach 0.5 mm.

In the present application, the contents of the IM layer and the low-resistance conductive layers (metal doped layer, transparent material conductive layer, and metal layer) can be referred to the contents described in the patent application nos. 2020103494526, 2020103494348, and 2020103488116.

Table 1 below shows the comparison result between the line width and the line spacing and the trace conductivity under different conditions between the prior art and the present application. Table 2 below shows the comparison of stress and appearance of the double-sided conductive film in different cooling methods of the prior art and the present application. The following items were tested using detection methods known in the art. Such as appearance detection mode and tool: and (4) visually observing under a 1000Lucas light source, wherein a stress measuring tool is a stress analysis detector.

In each embodiment, the properties of the same layer are the same unless otherwise specified.

Thickness of each layer: the total thicknesses of the Ag paste layer, the protective layer (CuNi), the Cu layer, the substrate layer (PET layer), the low-resistance conducting layer (ITO and metal layer, metal doped layer) and the IM layer (IM1 and IM2) are respectively 15nm, 10nm, 200nm, 125um, 90nm and 2.5 um. The results are as follows:

TABLE 1

TABLE 2

The data in the table show that the protective layer composed of the Cu layer and the Cu alloy replaces the original silver paste layer, so that the conductivity can be ensured on the premise of reducing the line width X-ray distance.

The double-sided conductive film in the present application has a low film stress, preferably 1 to 3N/m 2. For example, the stress of the single-face film can be 1N/m2 under the condition of adopting an air cooling mode. Under the stress, the appearances of two surfaces of the double-surface conductive film formed by the double-surface coating tend to be consistent, and the MD lines are qualified, namely less or no.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (9)

1. The double-sided conductive film is characterized by comprising a transparent base material, and a low-resistance conductive layer, a Cu layer and a protective layer which are sequentially stacked on two sides of the transparent base material;

the protective layer is a Cu alloy layer or a Mo alloy layer;

the low-resistance conducting layer is used for conducting electricity, and the resistance of the low-resistance conducting layer is not more than 100 ohms.

2. The double-sided conductive film according to claim 1, wherein the protective layer is a blackened layer.

3. The double-sided conductive film according to claim 2, wherein the single-sided stress of the double-sided conductive film is 1 to 3N/m 2.

4. The double-sided conductive film according to claim 1, further comprising IM layers respectively provided between the transparent substrate and each of the low-resistance conductive layers; the IM layer comprises an organic material layer and an inorganic material layer which are sequentially laminated on the transparent substrate.

5. The double-sided conductive film according to claim 4, wherein the low-resistance conductive layer comprises a first metal doped layer and a first transparent conductive material layer.

6. The double-sided conductive film according to claim 4, wherein the low-resistance conductive layer comprises a second metal doped layer, a second transparent conductive material layer, a third metal doped layer, and a third transparent conductive material layer.

7. The double-sided conductive film according to claim 4, wherein the low-resistance conductive layer includes a first metal layer, a fourth transparent conductive material layer, a second metal layer, and a fourth transparent conductive material layer.

8. A touch panel, wherein the touch panel is formed by laser etching the double-sided conductive film according to any one of claims 1 to 7, and a line width x a line distance formed by etching the Cu layer and the protective layer is 5um x 5um to 100um x 100 um.

9. The touch screen of claim 8, wherein the protective layer is a blackened layer, and a width of a border of the touch screen is 0.5mm to 2 mm.

Images