Patent Description:
In general, an electrostatic capacitance type touch panel uses an ITO-based conducting film, but the ITO has disadvantages in that, a realization speed is low by a RC delay of the ITO when applying the ITO to a large area touch panel, such that it is difficult to apply the ITO to the large area. In addition, in the case where a touch screen is manufactured by using a film on which the ITO is deposited, it is not easy to treat the touch screen due to cracks by bending of the ITO film. Among the disadvantages, in particular, in order to overcome a problem of enlargement by the RC delay, an effort for introducing an additional compensation chip has been made, but this has a problem in that a cost is increased. In order to overcome the problem, many companies are developing a technology for substituting an ITO conducting film by using a metal pattern. However, this technology has disadvantages in that in the case where a general single metal is used, because of high reflectance of the metal, a pattern is not realized well by a human eye in term of visibility and, with respect to external light, because of high reflectance and a haze value, glaring may occur. <CIT> discloses a structure body comprising a substrate, a conducting layer provided on at least one surface of a substrate, and a light absorption layer provided on at least one surface of the conducting layer, wherein the light absorption layer comprises, e.g., TiO<NUM>. <CIT> discloses a structure body comprising a substrate, a conducting layer provided on at least one surface of the substrate, and a light absorption layer provided on at least one surface of the conducting layer, wherein the light absorption layer comprises metals, metallic compounds, alloys and metal oxides as well as metal sulfides. <CIT> discloses a structure body comprising a substrate, a conducting layer provided on at least one surface of the substrate, and a light absorption layer provided on at least one surface of the conducting layer, wherein the light absorption layer does not comprise metal oxynitride. <CIT> discloses a structure body comprising a substrate, a conducting layer provided on at least one surface of the substrate, and a light absorption layer provided on at least one surface of the conducting layer, wherein the light absorption layer comprises silicon oxynitride. <CIT> discloses an antireflective layer system for a substrate, consisting essentially of an absorbing layer arranged on the substrate on a surface of said substrate toward an observer, said absorbing layer comprising at least one transition metal reacted with nitrogen and oxygen such that a transition metal oxynitride is formed, said absorbing layer having a thickness in the range <NUM> to <NUM>, and a transparent layer having a thickness in the range of <NUM> to <NUM> arranged on said absorbing layer. <CIT> discloses thin films suitable for display devices comprising a light absorbing material comprising one of the following: an inorganic semiconductor material such as silicon, germanium, silicon germanium, gallium arsenide, molybdenum oxide, tin oxide, bismuth oxide, vanadium oxide, nickel oxide, zinc oxide, gallium arsenide, gallium nitride and indium oxide.

<CIT> discloses a touch panel display comprising chromium oxynitride as an antireflection layer.

<CIT> discloses a touch panel disclosing values of the surface resistance of the conducting patterns.

The present invention has been made in an effort to improve visibility of a conducting pattern and a reflection property with respect to external light in a touch panel that comprises a conducting pattern provided in an effective picture portion, which is different from a known touch panel using an ITO-based conducting film.

The present invention provides a touch panel comprising:
a structure body, the structure body comprising:.

Yet another exemplary embodiment of the present invention provides a display comprising the touch panel and a display module.

According to the present invention, according to claim <NUM>, in a touch panel comprising a conducting pattern provided in an effective picture portion, it is possible to prevent reflection by the conducting pattern without affecting conductivity of the conducting pattern by introducing a light absorption pattern in a side observed by a user, and it is possible to improve a concealment property of the conducting pattern by improving light absorptivity. In addition, it is possible to further improve a contrast property of the touch panel by introducing the light absorption pattern as described above.

A structure body comprises: a substrate; a conducting layer provided on at least one surface of the substrate; and a light absorption layer provided on at least one surface of the conducting layer,.

The light absorption layer means a layer having light absorption, and may also be represented by a terminology such as a black layer or a dark color layer in addition to the light absorption layer.

In the structure body, a total reflectance measured in a direction of an opposite surface of a surface of the light absorption layer, which is contacted with the conducting layer, may be <NUM>% or less, <NUM>% or less, <NUM>% or less, and <NUM>% or less.

The total reflectance means reflectance of light of <NUM> that is incident at an angle of <NUM>° on a surface to be measured after an opposite surface of the surface to be measured is treated by a black layer (perfect black).

In the structure body, the light absorption layer is provided between the conducting layer and the substrate, and the total reflectance measured in a side of the substrate may be <NUM>% or less, <NUM>% or less, <NUM>% or less, and <NUM>% or less.

In the structure body, the total reflectance of light that is incident at an angle of <NUM>° on a surface to be measured of the light absorption layer is measured and illustrated in <FIG>.

As illustrated in the following <FIG> and <FIG>, in the case where the total reflectance to light of <NUM> is <NUM>% or less, preferably <NUM>% or less, more preferably <NUM>% or less, and much more preferably <NUM>% or less, it can be seen that the light absorption layer can sufficiently carry out its role.

A <NUM>° gloss value of the structure body may be <NUM> or less and <NUM> or less. A <NUM>° gloss value of the structure body may be <NUM> or less and <NUM> or less.

The <NUM>° gloss value of the structure body of <FIG> was <NUM>, and the <NUM>° gloss value was <NUM>. The <NUM>° gloss value of the structure body of <FIG> was <NUM>, and the <NUM>° gloss value was <NUM>. The <NUM>° gloss value of the structure body of <FIG> was <NUM>, and the <NUM>° gloss value was <NUM>.

An L value of a color range of the structure body may be <NUM> to <NUM> on the basis of a CIE color coordinate. In more detail, the L value of the color range of the structure body may be <NUM> to <NUM>, <NUM> to <NUM>, <NUM> to <NUM>, <NUM> to <NUM>, and <NUM> to <NUM> on the basis of a CIE color coordinate.

The L value of the color range of the light absorption layer of the structure body of the following <FIG> was <NUM> to <NUM> on the basis of a CIE color coordinate, and the L value of the color range of the light absorption layer of the structure body of the following <FIG> was <NUM> to <NUM> on the basis of the CIE color coordinate.

The structure body means a structure in which the substrate, the conducting layer, and the light absorption layer are laminated as separate layers, and a multilayered structure in which the conducting layer and the light absorption layer are sequentially deposited through a deposition process such as sputtering. The structure body may also be represented by a terminology such as a laminate and a multilayered structure body.

A touch panel according to the present invention comprises: a structure body, the structure body comprising:.

In the touch panel comprising the conducting pattern provided on an effective picture portion, it was found that a light reflection by the conducting pattern mainly affects visibility of the conducting pattern, and there was an effort for improving this. In detail, in a known ITO-based touch panel, because of high transmittance of the ITO, a problem due to reflectance of the conducting pattern is not largely shown, but it was found that reflectance and light absorption of the conducting pattern are important in the touch panel comprising the conducting pattern provided in the effective picture portion.

Therefore, in the touch panel, the light absorption pattern is introduced in order to improve a concealment property by decreasing reflectance of the conducting pattern. It is possible to improve the concealment property according to high reflectance of the conducting pattern by providing the light absorption pattern in a side observed by a user in the touch panel, if necessary, in both surfaces. In detail, since the light absorption pattern has light absorption, by decreasing the quantity of light that is incident on the conducting pattern and is reflected by the conducting pattern, reflectance by the conducting pattern may be decreased. It is preferable that the light absorption pattern has low reflectance as compared to the conducting pattern. Thereby, as compared to the case where the user directly observes the conducting pattern, reflectance of light may be decreased, such that visibility of the conducting pattern may be largely decreased.

In the touch panel the light absorption pattern may be provided on a surface facing a surface on which the display module is mounted among both surfaces of the conducting pattern. The light absorption pattern may be provided on both surfaces of the conducting pattern.

It is preferable that the total reflectance of the entire surface layer formed of a material constituting the light absorption pattern and a material constituting the conducting pattern is small, and the total reflectance may be <NUM>% or less, <NUM>% or less, <NUM>% or less, and <NUM>% or less. The material having the high total reflectance, such as Ag, Au or Al, may not be suitable to the light absorption pattern.

It is preferable that the total reflectance is small, but from the standpoint of selection of the material, the material in which the total reflectance of the entire surface layer is <NUM>% or more may be used.

In the touch panel the light absorption pattern comprises a first surface that is contacted with the conducting pattern and a second surface facing the first surface, and when the total reflectance of the structure body is measured in a side of the second surface of the light absorption pattern, the total reflectance (Rt) of the structure body may be calculated by the following Equation <NUM>.

In the case where two kinds of structure bodies are laminated in the constitution of the touch panel, the total reflectance (Rt) of the structure body may be calculated by the following Equation <NUM>.

Therefore, a difference between the case where there is a light absorption pattern and the case where there is no light absorption pattern depends on the reflectance of the light absorption pattern, and from this standpoint of view, as compared to the total reflectance (R0) of the structure body having the same constitution except for the case without the light absorption pattern, the reflectance may be decreased by <NUM> to <NUM>%, <NUM> to <NUM>%, <NUM> to <NUM>%, <NUM> to <NUM>%, and <NUM> to <NUM>%. That is, in the case where in Equations <NUM> and <NUM>, when the closure ratio range is changed from <NUM> to <NUM>% and the reflectance range is changed from <NUM> to <NUM>%, the maximum reflectance decrease effect of <NUM>% may be exhibited, and the minimum reflectance decrease effect of <NUM>% may be exhibited.

In the touch panel the light absorption pattern comprises a first surface that is contacted with the conducting pattern and a second surface that faces the first surface, and when the total reflectance of the structure body is measured in a side of the second surface of the light absorption pattern, a difference between the total reflectance (Rt) of the structure body and the total reflectance (R0) of the substrate may be <NUM>% or less, <NUM>% or less, <NUM>% or less, and <NUM>% or less.

In the touch panel the touch panel may further comprise an additional substrate provided on one side of the structure body, and when the total reflectance of the additional substrate provided on the structure body is measured in a side of the additional substrate, a difference with the total reflectance of the additional substrate may be <NUM>% or less, <NUM>% or less, <NUM>% or less, and <NUM>% or less.

Herein, the total reflectance means total reflectance of a touch sensor comprising the light absorption pattern.

In the present specification, when the incident light is <NUM>%, the total reflectance is preferably the measured value on the basis of the value of wavelength of <NUM> among reflected lights reflected by a target layer or a laminate on which light is incident, and this is because the total reflectance of the wavelength of <NUM> is not largely different from the entire total reflectance in general. For example, after the entire surface light absorption layer is formed by using a method for depositing a material constituting the light absorption pattern on the substrate, for example, a sputtering method, a CVD (chemical vapor deposition) method, a thermal evaporation method, and an e-beam deposition method, reflectance (<NUM>) of visible rays that are incident from an air side may be measured. In this case, on the rear surface of the substrate, that is, on a surface on which the light absorption layer is not formed, reflection on the rear surface of the substrate may be removed by performing the entire surface black treatment. As the substrate, a transparent substrate may be used, but the substrate is not particularly limited, and for example, glass, a plastic substrate, and a plastic film may be used.

In the touch panel the <NUM>° gloss value of the structure body may be <NUM> or less, and <NUM> or less. The <NUM>° gloss value of the structure body according to the exemplary embodiment of the present invention may be <NUM> or less, and <NUM> or less.

In the touch panel the L value of the color range of the structure body may be <NUM> to <NUM> on the basis of the CIE color coordinate. In more detail, the L value of the color range of the structure body may be <NUM> to <NUM>, <NUM> to <NUM>, <NUM> to <NUM>, <NUM> to <NUM>, and <NUM> to <NUM> on the basis of the CIE color coordinate.

In the touch panel a haze value of the structure body may be <NUM>% or less, <NUM>% or less, and <NUM>% or less.

In the touch panel according to the exemplary embodiment of the present invention, the light absorption pattern is provided between the conducting pattern and the substrate. The light absorption pattern may be provided between the conducting pattern and the substrate and on an opposite surface of a side of the conducting pattern which is contacted with the substrate.

The light absorptivity of the entire surface layer made of the material constituting the light absorption pattern is not particularly limited, but may be <NUM>% or more, <NUM>% or more, and <NUM>% or more.

The light transmittance of the entire surface layer made of the material constituting the light absorption pattern is not particularly limited.

The light absorption pattern may be formed by forming a light absorption layer by using a deposition method, for example, a method such as a sputtering method, a CVD (chemical vapor deposition) method, a thermal evaporation method, and an e-beam deposition method, and then patterning the light absorption layer. In particular, in the case where the sputtering method is used, a flexible property of the light absorption pattern is excellent. In the thermal evaporation method and e-beam deposition method, particles are simply stacked, but the sputtering method is defined in that particles form nucleus by collision and even though the nucleus grows and is bent, mechanical properties are excellent. In the case where the sputtering method is used, interface attachment ability between the light absorption pattern and another layer is excellent. By using the deposition method as described above, without using an adhesive layer or an attachment layer, a light absorption pattern may be directly formed on a substrate or a conducting pattern, and a desired thickness and a pattern shape may be implemented.

Herein, an insulation layer may be provided between the two laminates. The two laminates may be disposed in an opposite direction or the same direction. On both surfaces of the substrate, the conducting pattern and the light absorption pattern may be provided.

Examples of the laminate comprised in the touch panel are illustrated in <FIG> illustrate a laminating order of the substrate, the conducting pattern, and the light absorption pattern, and the conducting pattern and the light absorption pattern actually have a pattern shape instead of the entire surface layer.

<FIG> illustrates the case where the light absorption pattern is disposed between the substrate and the conducting pattern. In the case where a user observes the touch panel from a side of the substrate, the total reflectance by the conducting pattern may be largely decreased. <FIG> (not according to the invention) illustrates the case where the light absorption pattern is disposed on an opposite surface of a side of the conducting pattern which is contacted with the substrate. In the case where a user observes the touch panel from an opposite surface of a side of the substrate, the total reflectance by the conducting pattern may be largely decreased. <FIG> illustrates the case where the light absorption pattern is disposed between the substrate and the conducting pattern and on an opposite surface of a side of the conducting pattern which is contacted with the substrate. In both the case where a user observes the touch panel from a side of the substrate and the case where the user observes the touch panel from an opposite surface of a side of the substrate, the total reflectance by the conducting pattern may be largely decreased.

<FIG> illustrates a path of light that is incident on the light absorption pattern. A portion of light that is incident on the light absorption pattern may be reflected at the interface between the air layer and light absorption pattern, a portion of light may be absorbed into the light absorption pattern, a portion of light may be reflected at the interface between the light absorption pattern and substrate, and a portion of light may be transmitted through the light absorption pattern.

The light absorption pattern and the conducting pattern may be patterned simultaneously or separately, but layers for forming each pattern are separately formed. By forming the pattern as described above, while an effect of the light absorption layer pattern is optimized and maximized, it is possible to implement a fine conducting pattern required in an electrostatic capacitance type touch panel. In the electrostatic capacitance type touch panel, in the case where the fine conducting pattern is not implemented, physical properties required in the touch panel, such as resistance cannot be obtained.

Since the light absorption pattern and the conducting pattern form a laminated structure by a separate pattern layer, the structure is different from a structure in which at least a portion of a light absorption material is recessed or dispersed in a conducting pattern, or a structure in which a portion of a surface is physically or chemically deformed by performing surface treatment on a conducting layer of a single layer.

In the touch panel the light absorption pattern is directly provided on the substrate or the conducting pattern while an attachment layer or an adhesive layer is not disposed there between. An attachment layer or an adhesive layer may affect durability or optical properties. A method for manufacturing the laminate comprised in the touch panel is totally different from the case where an attachment layer or an adhesive layer is used. Moreover, as compared to the case where the attachment layer or adhesive layer is used, interface properties between the substrate or the conducting pattern and the light absorption pattern are excellent.

The thickness of the light absorption pattern is not particularly limited so long as the pattern has the above total reflectance. However, during the manufacturing process, in consideration of an etching property with the conducting pattern, it is preferable that the thickness is selected from <NUM> to <NUM>, but the preferable thickness may be different according to the used material and manufacturing process.

The light absorption pattern may be formed of a single layer, or a plurality of layers of two or more layers.

It is preferable that the light absorption pattern has an achromatic color, but the color thereof is not particularly limited thereto. In this case, the achromatic color means a color exhibited when light that is incident on a surface of an object is not selectively absorbed but evenly reflected with respect to a wavelength of each component.

As the material of the light absorption pattern, preferably, a material has the above total reflectance when an entire surface layer is formed may be used while not being particularly limited. For example, in a color filter, materials used as a material of a black matrix may be used. As the material of the light absorption pattern, a light absorption material to which antireflection function is provided is used.

The light absorption layer comprises of an oxynitride film, formed by using Mo, Al, or Cu under a deposition condition set by the person with ordinary skill in the art. The present inventors found that in the case where Mo, Al or Cu is used, as compared to the case of using the oxide, the case of using the nitride has optical properties more suitable for the light absorption pattern.

The light absorption pattern is provided in a region corresponding to the conducting pattern. Herein, the region corresponding to the conducting pattern means that the region has the pattern having the same shape as the conducting pattern. However, the pattern size of the light absorption pattern does not need to be completely identical to the conducting pattern, and the case where the line width of the light absorption pattern is narrower or wider than the line width of the conducting pattern is also comprised in the scope of the present invention. For example, it is preferable that the light absorption pattern has an area of <NUM> to <NUM>% of an area in which the conducting pattern is provided.

It is preferable that the light absorption pattern has a pattern shape having the line width equal to or larger than the line width of the conducting pattern.

In the case where the light absorption pattern has the pattern shape having the larger line width than the conducting pattern, when the user observes the pattern, an effect in which the light absorption pattern covers the conducting pattern may be increased, such taht there is an advantage in that an effect by gloss or reflection of the conducting pattern may be efficiently blocked. However, even though the line width of the light absorption pattern is the same as the line width of the conducting pattern, a target effect of the present invention can be accomplished. It is preferable that the line width of the light absorption pattern is larger than the line width of the conducting pattern by a value according to the following Equation <NUM>. <MAT> wherein.

For example, in the laminated structure like <FIG>, a calculation equation by Equation <NUM> is illustrated in <FIG>. Θ<NUM> is an angle obtained by modifying an angle (Θ<NUM>) between the vision of the user of the touch panel and the substrate by a refractive index of the substrate and a refractive index of a medium of a region in which the light absorption pattern and the conducting pattern are disposed, for example, an adhesive of the touch panel according to the Snell's law.

As an example thereof, assuming that an observer observes the laminate so that a value of Θ<NUM> is an angle of about <NUM>° and the thickness of the conducting pattern is about <NUM>, it is preferable that the line width of the light absorption pattern is larger than that of the conducting pattern by about <NUM> (<NUM> × tan(<NUM>) × <NUM>) on the basis of a lateral surface. However, as described above, even though the line width of the light absorption pattern is the same as that of the conducting pattern, a target effect can be accomplished. In order to form the structure of the light absorption layer and the conducting layer as described above, different etching conditions or deposition thicknesses may be applied by the person with ordinary skill in the art.

The material of the substrate may be appropriately selected according to the field to which the laminate is applied, and as preferable examples thereof, there are a glass or an inorganic material substrate, a plastic substrate or a film, but the material is not limited thereto.

The material of the conducting pattern is Aluminium or Copper. It is preferable that the material of the conducting pattern has excellent conductivity and can be easily etched. However, in general, the material having excellent conductivity has a disadvantage in that reflectance is high. However, because the light absorption pattern is used, it is possible to form the conducting pattern by using the material having the high reflectance. Even though the material having the total reflectance of <NUM> to <NUM>% or more is used, it is possible to decrease the reflectance through the light absorption pattern, decrease visibility of the conducting pattern, and maintain or improve a contrast characteristic.

Herein, the thickness of the conductive pattern is not particularly limited, but is preferably <NUM> to <NUM> in terms of the conductivity of the conductive pattern and the economic efficiency of the forming process thereof.

A specific resistance value measured while a laminate material formed of the material of the light absorption layer and the material of the conducting layer is considered as one material is preferably <NUM> × <NUM><NUM> ohm. cm to <NUM> × <NUM><NUM> ohm. cm, and more preferably <NUM> × <NUM><NUM> ohm. cm or less.

The method for forming the conducting pattern is not particularly limited, and the conducting pattern may be formed by using a direct printing method, or a method for patterning a conducting layer after forming the conducting layer may be used.

In the case where the conducting pattern is formed by using the printing method, ink or paste of the conducting material may be used, and the paste may further comprise a binder resin, a solvent or a glass frit in addition to the conducting material.

In the case where a conducting layer is formed, and then the layer is patterned, a material having an etching resist characteristic may be used.

The conducting layer may be formed by a method such as deposition, sputtering, wet coating, evaporation, electrolytic plating or electroless plating, and lamination of a metal foil. As the method for forming the conducting layer, a method in which organic metal, nano metal or a complex solution thereof is coated on the substrate, and then conductivity is provided by firing and/or drying may be used. As the organic metal, organic silver may be used, and as the nanometal, nanosilver particles may be used.

The patterning of the conducting layer may use a method using an etching resist pattern. The etching resist pattern may be formed by using a printing method, a photolithography method, a photography method, a method using a mask, or a laser transferring, for example, a thermal transfer imaging, and the printing method or the photolithography method is more preferable. The conducting pattern may be etched by using the etching resist pattern and the etching resist pattern may be removed.

The line width of the conducting pattern may be <NUM> or less, preferably <NUM> to <NUM>, more preferably <NUM> to <NUM>, and much more preferably <NUM> or less. The thickness of the conducting pattern may be <NUM> or less, preferably <NUM> or less, and more preferably <NUM> to <NUM>.

It is preferable that an opening ratio of the conducting pattern is <NUM>% to <NUM>%.

The conducting pattern may be a regular pattern or an irregular pattern.

As the regular pattern, a pattern shape of the art such as a mesh pattern may be used. The irregular pattern is not particularly limited, but may be a boundary line shape of figures constituting a Voronoi diagram. In the case where the irregular pattern and the light absorption pattern are used together, a diffracted pattern of reflected light by lighting having a directivity may be removed by the irregular pattern, and an influence by scattering of light may be minimized by the light absorption pattern, such that the problem in visibility may be minimized.

The pitch of the conducting pattern is preferably <NUM> or less and more preferably <NUM> or less, but this may be controlled by the person with ordinary skill in the art according to the desired transmittance and conductivity.

It is preferable that the surface resistance of the structure body comprising the substrate, the conducting pattern, and the light absorption pattern is <NUM> to <NUM> ohm/square. The surface resistance within the above range is advantageous in operating a touch panel.

Lateral surfaces of the light absorption pattern and the conducting pattern may have a positive taper angle, but the light absorption pattern or conducting pattern disposed on an opposite surface of the side of the conducting pattern which is contacted with the substrate may have a negative taper angle.

The touch panel may further comprise an additional structure body in addition to the above-mentioned structure body that comprises the substrate, the conducting pattern, and the light absorption pattern. In this case, as shown in <FIG>, two structure bodies may be disposed in the same direction, and as shown in <FIG>, two structure bodies may be disposed in an opposite direction. <FIG> and <FIG> illustrate the case where two structure bodies having the same structure are comprised, but the structure body comprised in the touch panel does not need to have the same structure, and any one, preferably, only the structure body that is the closest to the user may comprise the substrate, the conducting pattern, and the light absorption pattern, and an additionally comprised structure body may not comprise the light absorption pattern. Layer laminate structures in two or more structure bodies may be different from each other. In the case where two or more structure bodies are comprised, an insulation layer may be provided therebetween. In this case, the insulation layer may further have a function of an adhesive layer.

In the touch panel the conducting pattern and the light absorption pattern may be provided on both surfaces of the substrate, respectively.

The total reflectance of the touch panel constituted by the structure body that comprises the conducting pattern and the light absorption pattern may be <NUM>% or less, <NUM>% or less, <NUM>% or less, and <NUM>% or less.

Herein, the total reflectance of the touch panel means total reflectance of light that is incident from a side on which the light absorption pattern is provided, and is a value excluding the reflectance at an interface between the substrate and an air layer. Through controlling of reflectance by selection of the material constituting the light absorption pattern and controlling of the reflectance at an interface between the conducting pattern and the light absorption pattern, the thickness of the conducting pattern, and the shape of the pattern, the total reflectance of the entire structure body may be further controlled.

The touch panel may further comprise an electrode portion or a pad portion in addition to an effective picture portion on which the conducting pattern is formed on the structure body, and in this case, the effective picture portion and the electrode portion / pad portion may be constituted by the same conductor.

The touch panel may further comprise one or more films such as a protective film, a polarizing film, an antireflection film, an antiglaring film, a fingerprint-resistant film, and a low reflection film.

Provided is a method for manufacturing a touch panel.

Provides ia a method for manufacturing a touch panel, comprising: forming a conducting pattern on a substrate; and forming a light absorption pattern before, after, and before and after the conducting pattern is formed.

There is provided a method for manufacturing an electrostatic capacitance type touch panel, comprising: forming a conducting layer for forming a conducting pattern on a substrate; depositing a light absorption layer for forming a light absorption pattern before, after, and before and after the conducting layer is formed; and separately or simultaneously patterning the conducting layer and the light absorption layer.

In the manufacturing method, the material and forming method of the above each layer may be used.

The present invention provides a display comprising the touch panel and a display module.

Hereinafter, the present invention will be described in detail with reference to the Examples.

According to the invention, after the light absorption layer formed by using the Mo-based oxynitride was formed on the substrate, the conducting layer was formed thereon by using Cu. Subsequently, in order to measure the total reflectance, the entire surface black treatment was performed on the upper surface of the conducting layer, and the total reflectance (specular reflection / <NUM>) was measured by irradiating visible rays from the substrate. In this case, the reflectance was <NUM>%. The laminate according to Experimental Example <NUM> was illustrated in <FIG>.

According to the invention, after the light absorption layer formed by using the Al-based oxynitride was formed on the substrate, the conducting layer was formed thereon by using Al. Subsequently, in order to measure the total reflectance, the entire surface black treatment was performed on the upper surface of the conducting layer, and the total reflectance (specular reflection / <NUM>) was measured by irradiating visible rays from the substrate. In this case, the reflectance was <NUM>%.

According to the invention, after the light absorption layer formed by using the Cu-based oxynitride was formed on the substrate, the conducting layer was formed thereon by using Cu. Subsequently, in order to measure the total reflectance, the entire surface black treatment was performed on the upper surface of the conducting layer, and the total reflectance (specular reflection / <NUM>) was measured by irradiating visible rays from the substrate. In this case, the reflectance was <NUM>%.

According to the invention, after the light absorption layer formed by using the Al-based oxynitride was formed on the substrate, the conducting layer was formed thereon by using Cu. Subsequently, in order to measure the total reflectance, the entire surface black treatment was performed on the upper surface of the conducting layer, and the total reflectance (specular reflection / <NUM>) was measured by irradiating visible rays from the substrate. In this case, the reflectance was <NUM>%.

The same process as Experimental Example <NUM> was performed, except that the light absorption layer was not formed. In this case, the entire surface black treatment was performed on the back surface of the substrate, and the total reflectance (specular reflection/ <NUM>) was measured by irradiating visible rays into a side of the conducting layer. In this case, the reflectance was <NUM>%.

In the structure body manufactured like Experimental Example <NUM>, the total reflectance in the case where the user observed not a side of the light absorption layer but a side of the conducting layer was measured. To this end, the entire surface black treatment was performed on the back surface of the substrate, and the total reflectance (specular reflection/ <NUM>) was measured by irradiating visible rays into a side of the conducting layer. In this case, the reflectance was <NUM>%. The method for measuring the total reflectance according to Experimental Example <NUM> was illustrated in <FIG>.

The total reflectance of only the same substrate as used in Experimental Example <NUM> was measured. The total reflectance (specular reflection / <NUM>) of only the substrate was measured by performing the entire surface black treatment on one surface of the substrate and irradiating the visible rays into the opposite surface. The total reflectance of only the substrate was <NUM>%. The method for measuring the reflectance according to Experimental Example <NUM> was illustrated in <FIG>.

The total reflectance of the structure body manufactured in Experimental Example <NUM>, Experimental Example <NUM>, and Experimental Example <NUM> was illustrated in <FIG>.

As described above, in a touch panel comprising a conducting pattern provided in an effective picture portion, it is possible to prevent reflection due to the conducting pattern without affecting conductivity of the conducting pattern by introducing a light absorption pattern in a side observed by a user, and it is possible to improve a concealment property of the conducting pattern by improving light absorptivity. In addition, it is possible to further improve a contrast property of the touch panel by introducing the light absorption pattern as described above.

The microscope reflected light measurement result of the structure body of Experimental Example <NUM> was illustrated in the following <FIG>, and the solar light diffraction reflection pattern was observed and illustrated in the following <FIG>. The microscope reflected light measurement result of the structure body of Experimental Example <NUM> was illustrated in the following <FIG>, and the solar light diffraction reflection pattern was observed and illustrated in the following <FIG>.

The colority and total reflectance of the light absorption layer of the structure body of Experimental Example <NUM> were illustrated in the following <FIG>, and the colority and total reflectance of the light absorption layer of the structure body of Experimental Example <NUM> were illustrated in the following <FIG>. The colority and total reflectance of the light absorption layer of the structure body of Experimental Example <NUM> were similar to those of the following <FIG>.

Claim 1:
A touch panel comprising:
a structure body, the structure body comprising:
a substrate;
a conducting layer provided on at least one surface of the substrate; and
a light absorption layer provided on at least one surface of the conducting layer,
wherein the conducting layer is a conducting pattern and the light absorption layer is a light absorption pattern provided on at least one surface of the conducting pattern and provided on at least a portion of regions corresponding to the conducting pattern, wherein the light absorption pattern is provided between the conducting layer and the substrate,
characterized in that the light absorption layer comprises metal oxynitride, wherein the metal of the metal oxynitride is Mo and the conducting layer is Cu, the metal of the metal oxynitride is Al and the conducting layer is Al, the metal of the metal oxynitride is Cu and the conducting layer is Cu, or the metal of the metal oxynitride is Al and the conducting layer is Cu.