KR101919173B1 - Front surface protection plate for display device, and display device - Google Patents

Abstract

The front cover 10 for a display device of the present invention has a central display area A1 and an opaque area A2 formed on the outer periphery of the display area to shield visible light. And an infrared transmission window 4 for transmitting infrared light is provided in a part of the opaque region. The front cover 10 for a display device comprises a transparent substrate 1, a shielding layer 3 formed on the opaque area on one surface S2 side of the transparent substrate, a shielding layer formed as a non- And an infrared transmitting layer (2) laminated on a portion of the opaque region on the one surface side including the unformed portion of the shielding layer. The shielding layer shields at least visible light, and the infrared transmitting layer shields visible light and transmits infrared light. The infrared transmitting layer is formed in the entire region between the shielding layer including the unformed portion serving as the infrared transmitting window and the transparent substrate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a front plate for a display device,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a front cover for a display device and a display device having the same. More particularly, the present invention relates to a front shield plate for a display device provided with an infrared transmission window that transmits infrared light in an opaque region for shielding visible light, and a display device having the front shield plate.

2. Description of the Related Art In recent years, as a position input device used in combination with a display panel in various display devices such as a smart phone and a tablet PC (personal computer), a touch panel has been rapidly spreading. The touch panel has been known for various methods such as an electromagnetic induction method and a resistance film method, and has been used for various purposes. Recently, a touch panel of a capacitive type capable of multi-touch (multi-point simultaneous input) has been attracting attention.

Fig. 6 is a plan view schematically showing a mobile phone having a touch panel function such as a smart phone, as an example of the display device 200. Fig. A cellular phone having a touch panel function detects the approach of the skin in order to prevent malfunction of the touch panel or to turn off the display of the display panel and prolong the life of the battery And a seal sensor. As this seal sensor, an infrared sensor is used. 6, the seal sensor is provided with an infrared ray transmission window 4 in a part of a case 50 in which the front protective plate 40 for a display device is inserted, and the infrared ray transmission window 4, As shown in Fig.

7 is a diagram schematically showing an example of major components of the display device 200 provided with the touch panel 20 shown in Fig. Fig. 7 does not show the case 50 in which the infrared transmission window 4 is provided. 7 (a) is an exploded plan view, and Fig. 7 (b) is a cross-sectional view of the display device when the front protective plate 40 for a display device is cut with the CC line shown in the exploded plan view of Fig. Sectional view showing the front cover 40 for the front cover. The touch panel 20 is disposed on the front side of the display surface of the display panel 30 (the front side of the drawing in Fig. 7A), which is the emission side of the display light from the display panel 30. [ For protecting the touch panel 20, the front cover 40 for the display device is disposed on the side of the touch panel 20 on the side from which the display light from the display panel 30 emerges (JP 2009 -193587 A, JP 3153971 U, JP 2008-266473 A). 7, the opaque area A2 is formed on the outer periphery of the display area A1. The opaque area A2 is provided with a shielding layer 5 for shielding visible light Is formed. This opaque area A2 hides the wiring 9 and the connectors disposed on the outer periphery of the touch panel 20 disposed on the other side of the display front cover plate 40 so as not to damage the appearance. In the opaque area A2, visibility information 6 such as a product logo is appropriately provided, and the opaque area A2 is also a decoration part of the front cover 40 for the display device.

In order to suppress the loss of the display light due to the interface reflection or to reduce the reflection of the external light so as to make the display easier to see, the display between the front cover 40 for the display device and the touch panel 20, The panels 30 may be filled with a resin layer without gaps and laminated in close contact with each other. In order to meet the demand for thinning, weight saving, and reduction in the number of parts, it is preferable that the touch panel 20 is integrated with the front panel 20 and the display panel 30, Various forms have been proposed (JP 2009-193587 A, JP 3153971 U).

However, there is a case where the infrared transmission window 4 is required to be provided on the front cover 40 for the display device. This is because the infrared transmission window 4 is not placed in the case 50 of the display device 200 but is put into the part of the front cover 40 for the display device, It is possible to cope with a wider design. For example, the infrared transmission window 4 may be provided on a part of the front cover 40 for the display device, and the area of the front cover 40 for the display device may be made wider, 50 can be designed to be thin.

7, if the front cover 40 for the display device has a structure having the shielding layer 5, the shielding layer 5 is usually formed by screen printing, and its thickness is, for example, 6 to 10 탆 thick. Therefore, when the space between the front panel shielding plate 40 for the display device and the touch panel 20 is filled with the resin layer, air is formed as residual bubbles in the vicinity of the stepped portion generated by the film thickness of the shielding layer 5 There is a problem that it is easy to leave. In the case where the shielding layer 5 having a large film thickness is integrated with the front panel shielding plate 40 and the touch panel 20 in the case of integrating the shielding layer 5 for the position detection of the touch panel 20 There is also a problem that when the transparent electrode is formed by the sputtering method or the like, it is easily broken at the stepped portion. The problem of the step difference in the rim portion caused by the film thickness of the shielding layer 5 is improved by forming the shielding layer 5 to be as thin as 5 mu m or less. In this case, for example, by forming the shielding layer 5 by a photolithography method using a photosensitive resin instead of forming the shielding layer 5 by a screen printing method, the problem of bubbles and broken lines can be improved. However, when the shielding layer 5 is formed by photolithography using a photosensitive resin, it has been found that there is another new problem. This is a problem in that the adhesiveness under high temperature and high humidity, which does not occur when the thickness of the shielding layer 5 on which the shielding layer 5 is formed by screen printing is large, is lowered.

That is, an object of the present invention is to provide an infrared transmission window in an opaque region in which a shielding layer is formed, while improving the adhesiveness of the shielding layer under high temperature and high humidity, in a front shielding plate for a display device. It is another object of the present invention to provide a display device provided with a front shield plate for a display provided with such an infrared transmission window.

The front shield plate for a display according to the present invention has a display region at the center and an opaque region formed at the outer periphery of the display region for shielding visible light, A front shield plate for a display device having a transmission window,

A light-

A shielding layer formed on the opaque region on at least one surface side of the first surface of the transparent substrate and the second surface opposite to the first surface, the shielding layer at least covering the visible light, A shielding layer formed as an active portion,

And an infrared transmitting layer which is laminated on a portion of the opaque region on the side of the one surface including the unformed portion of the shielding layer and which shields visible light and transmits infrared light,

The infrared transmitting layer is formed in the entire region between the shielding layer and the transparent substrate including the unformed portion serving as the infrared transmission window.

In the front shield plate for a display device according to the present invention, the shielding layer includes a coloring pigment, which may include a black pigment, in a resin binder comprising a cured product of a photosensitive resin,

Wherein the infrared transmitting layer contains a colored pigment in a resin binder comprising a cured product of a photosensitive resin,

The colored pigments of the infrared transmitting layer may contain at least three kinds of colored pigments in a pattern of a black non-formed portion which are colors different from each other.

In the front shield plate for a display device according to the present invention, the infrared transmitting layer may be disposed between the transparent substrate and the shielding layer adjacent to the transparent substrate and the shielding layer.

In the front shield plate for a display device according to the present invention, the first surface of the transparent substrate may face the front side, and the infrared transparent layer may be disposed on the second surface of the transparent substrate.

In the front shield plate for a display device according to the present invention, the shielding layer may have one surface adjacent to the infrared transmitting layer and another surface located on the opposite side to the one infrared transmitting layer,

A transparent electrode for position detection of the touch panel is formed on the other surface side of the shield layer,

The transparent electrode may extend from the display area to the opaque area and be electrically connected to the opaque wiring disposed in the area overlapping the shield layer with the opaque area.

A display device according to the present invention comprises a front panel protective plate for a display device having any one of the above features and a display panel.

In the display device according to the present invention, the display panel may be disposed on the one surface side of the transparent substrate.

The display device according to the present invention may further comprise a touch panel between the front panel protection plate for the display device and the display panel, wherein the touch panel is extended from an area overlapping the display area to an area overlapping the opaque area A transparent electrode, and an opaque wiring disposed in an area overlapping the shielding layer,

And the transparent electrode may be electrically connected to the opaque wiring in an area overlapping the opaque area.

In the display device according to the present invention, the display panel may be a liquid crystal panel or an electroluminescent panel.

According to the present invention, the infrared ray shielding window can be provided in the opaque region where the shielding layer is formed, while improving the adhesion of the shielding layer under high temperature and high humidity.

1 (a) and 1 (b) are views for explaining an embodiment of a front shielding plate for a display device according to the present invention, wherein FIG. 1A is a plan view, Sectional view taken along a line CC in Fig. 1 (a). Fig.
2 is a graph illustrating the relationship between visible light and transmittance spectrum in the infrared transmitting layer.
3 is a cross-sectional view illustrating another embodiment of the front shield plate for a display device according to the present invention.
FIG. 4A is a plan view of the front shielding plate for the display device shown in FIG. 3, and FIG. 4B is a partial view showing the transparent electrode shown in FIG. 4A.
5 is a cross-sectional view schematically illustrating one embodiment of a display device provided with a front shield plate for a display device shown in Fig.
6 is a plan view showing an example of a conventional display device provided with an infrared transmission window;
Fig. 7 is a diagram schematically showing an example of main components of the display device shown in Fig. 6, wherein Fig. 7 (a) is an exploded plan view, Fig. 7 (b) Fig.
8 is a cross-sectional view showing another example of a front shield plate for a conventional display device.
9 is a sectional view showing still another example of a front shield plate for a conventional display device.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, one embodiment of the present invention will be described with reference to the drawings. Further, the drawings are conceptual diagrams, and for convenience of explanation, the scale and the aspect ratio of the components may be exaggerated as appropriate.

[A] Definition of terms:

Hereinafter, the definition of the main terms used in this specification will be described here.

When the front protective plate 10 for the display device is used in combination with the display panel 30 in the front protective plate 10 or other components for the display device, Refers to the side from which display light is emitted and the side from which the image from the display panel 30 is observed. Means a side opposite to the above-mentioned " measurement ", and means a side where the display light of the display panel 30 is incident on the front protective plate 10 or other components for the display device. The terms "first surface" and "second surface" may be any of the above-mentioned "front side" and "front side". In the present embodiment, the surface on the side having the shielding layer 3 and the infrared transmitting layer 2 is referred to as a " second surface ". Normally, the second surface is the surface on the opposite side.

[B] Front panel for display device:

A front shield plate for a display device according to this embodiment will be described with reference to an embodiment shown in Fig. 1 (a) is a plan view, and Fig. 1 (b) is a cross-sectional view taken along a line C-C shown in Fig. 1 (a).

As shown in the plan view of Fig. 1 (a), the front shield plate 10 for a display device of the present embodiment has a central display area A1 and a display area A1 formed on the outer periphery of the display area A1 to shield visible light An opaque region A2, and a part of the region of the opaque region A2 is provided with an infrared transmission window 4 for transmitting infrared light.

As shown in the cross-sectional view of Fig. 1 (b), the front protective plate 10 for a display according to the present embodiment includes a transparent substrate 1, a first surface S1 of the transparent substrate 1, Shielding layer 3 formed on the opaque area A2 on the second surface S2 side of the two surfaces of the second surface S2 opposite to the first surface S1 and shields the infrared light together with the visible light, (3) which is formed as a non-forming portion and which is formed as a non-forming portion (4) on the second surface (S2) side, and a portion And an infrared transmission layer 2 which shields visible light and transmits infrared light. Since the shielding layer 3 does not transmit infrared light, that is, it has a shielding property (light shielding property) against infrared light, the portion to be made into the infrared transmission window 4 is a non-formed portion. On the other hand, the infrared transmitting layer 2 is formed in the entire region between the transparent substrate 1 and the shielding layer 3 as well as the non-formed portion of the shielding layer 3 in the portion to be the infrared transmitting window 4, Respectively. The infrared transmitting layer 2 and the shielding layer 3 are both formed on the opaque region A2 on at least one side of the first surface S1 and the second surface S2 of the transparent substrate 1, And the one surface may be either the first surface S1 or the second surface S2.

The shielding layer (3) is a layer containing a colored pigment in a resin binder containing a cured product of a photosensitive resin. In the present embodiment, the colored pigment includes a black pigment including an inorganic substance such as carbon black and titanium black, and is a layer expressing black.

The infrared transmitting layer (2) is a layer containing a colored pigment in a resin binder containing a cured product of a photosensitive resin. Further, the colored pigment has a color different from that of the colored non- Specifically, three kinds of red, yellow, and blue are included to represent a black color of the same color as that of the above-mentioned shielding layer 3, and it is also an infrared transparent layer.

In this embodiment, the infrared transmitting layer 2 and the shielding layer 3 are formed on the second surface S2 of the transparent substrate 1 in this order. In the present embodiment, the second surface S2 faces the first surface S1 and the second surface S2 faces the touch panel 20 or the display panel 30, and in other words, It is assumed that the first surface S1 faces the viewer V side.

The infrared transmitting layer 2 and the shielding layer 3 are all coated with a colored photosensitive resin composition containing a colored pigment and an uncured resin of a photosensitive resin on the transparent substrate 1 and patterned by photolithography, The total thickness of the infrared transmitting layer 2 and the shielding layer 3 is 5 占 퐉 or less.

With the above configuration, in the display front protective plate 10 according to the present embodiment, the infrared transmission window 4 is formed in the region of the opaque region A2 having the shielding layer 3, ) Can be formed while improving the adhesion under high temperature and high humidity. In the opaque area A2, the color of the part of the infrared transmission window 4 and the color of the part without the infrared transmission window 4 can be the same color, and the infrared transmission window 4 can be made of a product Design can be done. Further, by adjusting the ratio of the three or more kinds of colored pigments used in the infrared transmitting layer 2, the color taste of the reflection color can be adjusted even when the expression color is black. In addition, the color taste can be adjusted by adjusting the color taste of the entire area of the opaque region A2 in that the infrared transparent layer 2 is formed not only in the infrared transmission window 4 but also in the entire region of the formation portion of the shielding layer 3 .

Hereinafter, each component will be described in more detail.

[Display area A1 and opaque area A2]

As shown in the plan view of FIG. 1 (a), the front cover 10 for a display device has a display area A1 at the center and an opaque area A2 for shielding visible light at the outer periphery of the display area A1 . An infrared transmission window (4) is provided inside the opaque area (A2). 1 (b), when the display area 30 is applied to the display panel 30 indicated by the imaginary line of the alternate long and short dash line, the display area A1 transmits the display light from the display panel 30 to display the image It is an area that can be. The opaque area A2 is formed by hiding wiring, a connector, and the like disposed on the outer peripheral portion of the display panel 30, or by applying to the touch panel 20 indicated by the imaginary line of the dashed line in the sectional view of Fig. 1 (b) Is an area for hiding or holding opaque wires, connectors, and the like disposed on the outer periphery of the touch panel 20. The opaque area A2 is an area which becomes a decoration part by the color represented by the color, the visibility information 6 such as a logo or mark to be installed properly.

[Infrared transmission window (4)]

In the present embodiment, the infrared transmission window 4 is provided in a region of the opaque region A2 and shields visible light and transmits infrared light. By providing the infrared transmission window 4 on the front cover 10 for the display device, it is possible to detect the infrared ray at a portion overlapping the infrared transmission window 4 of the display device to which the front cover 10 for the display device is applied It becomes possible to install an infrared light-utilizing component such as a seal sensor to be used. The infrared light-utilizing part provided on the infrared transmission window 4 may be a pattern of a non-seal sensor part, and is not particularly limited as long as it uses infrared light. For example, the infrared transmission window 4 may be used as an infrared communication port for transmitting and receiving information.

As described above, in the present embodiment, since the front cover 10 for the display device itself has the infrared transmission window 4, it is not necessary to provide the infrared transmission window in the case of the display device. As a result, in the case of the display device, the frame portion surrounding the front cover 10 for the display device is narrowed so that the area of the portion where the front cover 10 for the display device is exposed is widened, . In addition, since the infrared transmission window 4 is provided in the opaque area A2 of the front cover 10 for the display device, not in the case of the display device in which the front cover 10 for the display device is housed, There is no possibility of damage.

[Transparent substrate (1)]

The translucent substrate 1 has a mechanical strength capable of protecting these surfaces with respect to the touch panel 20 or the display panel 30 that transmits at least visible light and infrared light and applies the front protective plate 10 for a display device There is no particular limitation, and a glass plate can be typically used. Particularly, as the glass plate, the chemical tempered glass is preferable in that the mechanical strength is superior to that of the float glass, and the thickness can be reduced accordingly. The chemically tempered glass is typically a glass whose mechanical properties are enhanced by a chemical method in which ion species are partially exchanged, such as by replacing sodium with potassium in the vicinity of the surface of the glass. Particularly, in this embodiment, even when the transparent substrate 1 is chemically tempered glass, the infrared transmitting layer 2 also functions as a close adhesion strengthening layer of the shielding layer 3 to the transparent substrate 1, It is possible to improve the adhesiveness of the two transparent substrates 1 of the transparent layer 3 and the infrared transmitting layer 2 under high temperature and high humidity. In this respect, chemically tempered glass as the transparent substrate 1 is one kind of preferable substrate. Resin can also be used for the transparent substrate 1. For example, as the resin, an acrylic resin, a polycarbonate resin, a cycloolefin resin, a polyester resin, or the like can be used. By using a resin for the transparent substrate 1, it is possible to make it light in weight and also to have flexibility.

[Infrared transparent layer (2)]

The infrared transmitting layer 2 exemplified in Fig. 1 is formed in a portion of the opaque area A2 of the second surface S2 of the transparent substrate 1 facing the touch panel 20 and the display panel 30 side . The infrared transmitting layer 2 is formed not only in the portion of the infrared transmission window 4 in the opaque region A2 but also in the entire region thereof. In other words, in the sense of ensuring the infrared transmittance, it is also formed in the entire region between the transparent substrate 1 and the shielding layer 3 in the opaque region A2 although it is originally formed only in the infrared transmission window portion. This is because the infrared transmitting layer 2 not only corresponds to the infrared transmitting window 4 but also functions as an adhesion strengthening layer for improving the adhesion of the shielding layer 3 and the translucent substrate 1 under high temperature and high humidity . Therefore, the shielding layer 3 is not directly in contact with the surface of the transparent substrate 1 but is formed therebetween through the infrared transmitting layer 2. The infrared transmitting layer 2 functions as a base for the transparent substrate 1 of the shielding layer 3 and also functions as an adhesion enhancing layer so that the light transmitting substrate 2 on both the shielding layer 3 and the infrared transmitting layer 2 1) under high temperature and high humidity is improved. The infrared transmitting layer 2 is formed in the non-forming portion of the shielding layer 3 forming the forming portion of the shielding layer 3 and the infrared transmitting window 4 in the opaque region A2, May be formed in another region in the region of the opaque region A2, such as the vicinity of the outside of the outer contour of the shielding layer 3. [ In this case, the portion where only the infrared transmitting layer 2 is formed outside the outer contour of the shielding layer 3 forms the opaque region A2 by the light shielding property of the infrared transmitting layer 2 with respect to visible light. For example, the outer contour of the infrared transmitting layer 2 may be made slightly larger so as to include the outer contour of the shielding layer 3 on the inner side, and when the positional deviation occurs during the formation of the infrared transmitting layer and the shielding layer 3 , This can be made inconspicuous.

The transmittance of the infrared transmitting layer 2 with respect to the infrared light depends on the required specification, the color of expression, and the infrared-use component such as an infrared sensor applied to the infrared transmitting window 4. 80% or more. In this embodiment, the transmittance in the infrared region is used. The infrared region in which the transmittance is 80% or more does not necessarily have to be 780 nm or more. For example, if the region is 850 nm or more, the infrared region can be sufficiently dealt with. In addition, the upper limit of the infrared region in which the transmittance is 80% or more is the near infrared region, which is usually sufficient to be 1300 nm. The light shielding property of the infrared transmitting layer 2 with respect to the visible light depends on the required specification and the color of expression but the portion only of the infrared transmitting layer 2 overlapping with the infrared transmitting window 4 is usually small as a spot, It is not necessary to match the layer 2 and the shielding layer 3 to the level of the light shielding property of the laminated portion. Accordingly, the light-shielding property of the infrared light-permeable layer 2 alone to visible light is not more than 50% (at least 0.2 at the optical density OD), more preferably not more than 25% at the transmittance Optical density OD 0.6 or more), and more preferably 10% or less (optical density OD 1.0 or more) in transmittance. In the present embodiment, the infrared transmitting layer 2 has a transmittance of 80% or more at a wavelength of 850 nm or more and 1300 nm or less with respect to an infrared light region, and a transmittance of 10% or less with respect to a visible light region. The transmittance is not an average value but a value for each wavelength.

The infrared transmitting layer (2) is made of a layer containing a coloring pigment in a resin binder containing a cured product of a photosensitive resin. The method of forming the infrared transmitting layer 2 is not particularly limited. For example, after a colored photosensitive resin composition containing a colored pigment and an uncured resin of a photosensitive resin is coated on the surface of the transparent substrate 1, The infrared transmitting layer 2 can be formed by a so-called photolithography method in which the resist is exposed and developed in the pattern of the transparent layer 2. In the present embodiment, the infrared transmitting layer 2 is formed by a photolithography method. The infrared transmitting layer 2 formed by photolithography using the photosensitive resin composition can be easily formed to have a thin film thickness of, for example, 3 탆 or less as compared with the screen printing method, and the infrared transmitting layer 2 (2) and the shielding layer (3) generated at the boundary between the formation portion of these two layers and the non-formation portion in the two-layer lamination portion in which the transparent layer (2) and the shielding layer It is preferable in that the step difference of the surface can be reduced. The film thickness of the infrared transmitting layer 2 formed by photolithography using the photosensitive resin composition can be specifically set to 0.2 to 3 탆. In addition, even when the infrared transmitting layer 2 is made to have the same color as the shielding layer 3, for example, black, the light shielding property as the opaque region A2 is set to be higher than the light shielding property of both the infrared transmitting layer 2 and the shielding layer 3 It is preferable that the thickness of the infrared transmitting layer 2 is 0.3 占 퐉 or more so that the light shielding property as a whole can be obtained.

In the present embodiment, the infrared transmitting layer 2 is formed in a pattern in the opaque area A2, but the method of forming the pattern is not limited to the photolithography method, but the infrared transmitting layer 2 and the shielding layer 3, Other pattern formation methods such as the above-mentioned screen printing method, inkjet printing method, and the like may be used as long as the problem of the level difference due to the step difference can be solved. However, as described above, in comparison with the screen printing method, the photolithography method can be applied to one type of the preferable forming method in view of the fact that the problem of the step difference can be made thin enough to effectively solve the problem, to be.

[Coloring Pigment]

The colored pigment used in the infrared transmitting layer 2 in the present embodiment means a colored pigment other than a black pigment showing black, in other words, a colored pigment other than black. Examples of the black pigment showing black are titanium black (lower titanium dioxide, titanium oxynitride, etc.), carbon black and the like. On the other hand, in the present embodiment, the infrared transmitting layer 2 expresses black using a coloring pigment other than black. As the color pigments other than black, for example, red pigments, yellow pigments, blue pigments, green pigments, and purple pigments can be used. As described above, by using a coloring pigment without using an inorganic black pigment such as titanium black (low-order titanium oxide, titanium oxynitride) and carbon black as the coloring pigment, visible light is shielded by the infrared transmitting layer 2 The external light can impart the optical characteristics to be transmitted. It is also possible to equally color match with the color of the shielding layer 3 in the same color system. The color of the infrared transmitting layer 2 is preferably the same color as the color of the shielding layer 3 in view of the design unity of the opaque region A2.

The red pigment is, for example, a red pigment such as a diketopyrrolopyrrole type, an anthraquinone type or a perylene type. The yellow pigment is, for example, a yellow pigment such as isoindolinone type or anthraquinone type, For example, a blue pigment such as a copper phthalocyanine type or an anthraquinone type. The green pigment is, for example, a green pigment such as phthalocyanine type or isoindolin type. Specific examples thereof include diketopyrrolopyrrole-based red pigments such as Pigment Red 254 (PR254), red pigments such as Pigment Red 177 (PR177), and red pigments such as Pigment Yellow 139 (PY139) Indolin yellow pigments, and copper phthalocyanine blue pigments such as pigment blue PB15: 6 (PB15: 6). In the purple color pigment, a quinacridone purple pigment such as Pigment Violet 23 (PV23) may be used. In addition, a coloring pigment showing a color other than these, that is, a color, may be used. The size of the particles of the colored pigment is 1 mu m or less in average particle diameter, preferably about 0.03 to 0.3 mu m.

In the present embodiment, the colored pigments contained in the infrared transmitting layer 2 include at least three kinds of color pigments other than black, which are different colors from each other. The combination of the coloring pigments of different colors may be, for example, a combination of the red coloring pigment, the yellow coloring pigment and the blue coloring pigment. The combination of the three colors of red, yellow and blue can be obtained by adjusting the content of the color pigment of each color so that black can be expressed without including a black pigment and also a wide variety of chromatic colors can be expressed, Lt; / RTI > The combination of the three kinds of colored pigments including the three colors is preferable in that a color which is different from each other and which can not be expressed by combination of two kinds of colored pigments other than black can be widely expressed in a wide variety. Further, as with the violet pigment, for example, when a coloring pigment other than three colors is added to the combination of the three colors, a wider color can be expressed. For example, a combination of four kinds of four colors may be used by further containing a purple pigment.

In a combination of the red coloring pigment, the yellow coloring pigment and the blue coloring pigment, preferred specific examples of the respective coloring pigments include red color pigments of anthraquinone type or diketopyrrolopyrrole type red pigments, yellow coloring pigments Isophorone based yellow pigments, and blue colored pigments include copper phthalocyanine based blue pigments. More specifically, for example, Pigment Red 177 (PR177) is used as the red pigment of the anthraquinone type, more preferably Pigment Red 254 (PR254) is used as the diketopyrrolopyrrole type red pigment, (PB15: 6) is used as a blue pigment of copper phthalocyanine system, Pigment Yellow 139 (PY139) is used as an isoindolinone yellow pigment, and Pigment Blue PB15: 6 (PB15: 6) is used as a copper phthalocyanine type pigment. By this combination of three colors, it is possible to express black that has no color difference compared with black color by carbon black.

The graph of the transmittance spectrum shown in Fig. 2 shows an example of the transmittance spectrum of the infrared transmitting layer 3 when black is expressed by the combination of the coloring pigments of the three colors other than black as described above. As described above, the infrared transmittance at a transmittance of 50% or more is obtained in an infrared region having a wavelength of 800 to at least 1300 nm, more specifically a near infrared region and at least a wavelength of 1300 nm or less. When the wavelength is 850 nm or more, An infrared transmittance of 90% or more is obtained with a transmittance of 80% or more. On the other hand, in a visible light region of wavelengths of 380 to 780 nm, it can be seen that light shielding properties for visible light with a transmittance of 5% or less at each wavelength can be obtained.

In the present embodiment, black is represented by including three kinds of colored pigments other than black, which are different colors from each other. However, in the present embodiment, three kinds or more of color pigments other than black The effect of adjusting the color taste of the reflection color can be obtained even when the same black color is used as compared with the case where black color is expressed by the black pigment. This is because even the same black color, for example, is bluish black or reddish black. For example, when the display panel 30 to which the front protective plate 10 for a display device is applied is a liquid crystal display panel, the black color of the display area A1 in the non-display state when the backlight is turned off, The display area A1 in which the color of the non-display state of the display panel 30 is reflected by bringing the color taste of the opaque area A2 by the one infrared transmitting layer 2 and the shielding layer 3 close to each other, It is possible to adjust each of the colors of the opaque area A2 in which the color of the transparent layer 2 and the color of the shielding layer 3 is reflected to be a harmonized overall appearance. The function of expressing the color by the infrared transmitting layer 2 is such that only the constitution in which the infrared transmitting layer 2 is formed in the entire region of the formation portion of the shielding layer 3 as well as the infrared transmitting window 4 .

The content of the coloring pigment in the infrared transmitting layer 2 depends on the visible light shielding property and the infrared light permeability which are required but the amount of the coloring pigment relative to the total solid content of the infrared transmitting layer 2 including the coloring pigment and the resin binder In terms of pigment concentration, for example, usually 10 to 60%, preferably 20 to 40%. In other words, the coloring pigment is usually in the range of 10 to 60 parts by mass, preferably 20 to 40 parts by mass based on 100 parts by mass of the total solid content of the infrared transmitting layer (2). The content of the coloring pigment is the total amount of the coloring pigments in total of all the coloring pigments of different colors. If the content of the colored pigment is less than the above range, the ratio of the resin binder in the infrared transmitting layer 2, which is considered to contribute to the adhesion, is increased, and the adhesion of the infrared transmitting layer 2 itself under high temperature and high humidity, Is advantageous from the viewpoint of the effect of improving the adhesion between the shielding layer 3 and the transparent substrate 1 under high temperature and high humidity with respect to the shielding layer 3 but the light shielding property against visible light is reduced, It is difficult to make the thickness 5 mu m or less, which is not preferable. If the color pigment exceeds this range, it is advantageous in terms of visible light shielding property, but in particular, the effect of improving the adhesion of the infrared transmitting layer 2 itself under high temperature and high humidity is deteriorated. Further, , It is not preferable from the viewpoint of the effect of improving the adhesion of the shielding layer 3 and the translucent substrate 1 under high temperature and high humidity. In order to satisfy the infrared light transmittance, especially the effect of improving the adhesion and the visible light shielding property, it is preferable to set the above range.

As described above, by not using a black pigment such as carbon black or titanium black as the coloring pigment of the infrared transmitting layer 2, it is possible to impart optical characteristics that shield visible light but transmit infrared light, Although the reason for this is not clear, the thickness of the infrared transmitting layer 2 can be made thin, and therefore, the adhesion of the infrared transmitting layer 2 itself under high temperature and high humidity, when formed as a cured layer of a favorable photosensitive resin, It is possible to improve the adhesion between the shielding layer 3 and the transparent substrate 1 under high temperature and high humidity by interposing the infrared transmitting layer 2 therebetween.

By the way, if the infrared transmission window 4 in harmony with the color of the shielding layer 3 is provided in the opaque area A2 by simply using the infrared transmission layer 2, After forming a shielding layer 3 having a non-formed portion in the infrared transmission window 4 on the transparent substrate 1, like the front shielding plate 50 for the device, (2). However, this configuration can not improve the adhesion of the shielding layer 3 under high temperature and high humidity. The boundary between the shielding layer 3 and the infrared transmitting layer 2 is exposed to the transparent substrate 1 and the landing region filled with the infrared transmitting layer 2 in the non-forming portion of the shielding layer 3 is visible It is clear. As another constitution, by using the characteristic of the infrared transmitting layer 2 having a light shielding property against visible light, like the front shielding plate 50 for a display device as another reference example, which is exemplified in the sectional view of Fig. 9, It is also conceivable to form the opaque region A2 only with the transparent region 2 and to make the necessary portion in the infrared transparent window 4 in this region. However, in this structure, it is difficult to achieve both the shielding property to sufficient visible light and the transparency to sufficient infrared light. Particularly, when the expression color is black, it is remarkable.

[Photosensitive resin]

Examples of the photosensitive resin as the resin component of the resin binder that disperses and / or retains the color pigment include reactive vinyl groups such as acrylic resins, epoxy resins, polyimide resins, polyvinyl cinnamate resins, At least one photosensitive resin having a photoreactive group can be used. In the acrylic resin, for example, a photosensitive resin including an alkali-soluble resin, a polyfunctional acrylate monomer, a photopolymerization initiator, and other additives may be used as the resin component of the resin binder.

As the alkali-soluble resin, a methacrylic acid ester copolymer such as a benzyl methacrylate-methacrylic acid copolymer or the like, or a resin such as an epoxy acrylate having a bisphenol fluorene structure may be used. Examples of the polyfunctional acrylate monomers include trimethylolpropane tri (meth) acrylate, pentaerythritol tetra (meth) acrylate, dipentaerythritol penta (meth) acrylate, dipentaerythritol hexa ) Acrylate may be used. Further, in the present embodiment, (meth) acrylate means either methacrylate or acrylate.

As the photopolymerization initiator, at least one of alkylphenone, oximeester, triazine, and titanate may be used. For example, in the alkylphenone system, (2-methyl-1- [4- (methylthio) phenyl] -2-morpholinopropane-1-one (Irgacure (registered trademark) 907, BASF Japan Co., (Irgacure (registered trademark) 369, manufactured by BASF Japan K.K.)) or an oxime ester system in the case of 2-benzyl-2-dimethylamino-1- (4-monopolyphenyl) butanone- 1,2-octanedione, 1- [4- (phenylthio) phenyl] -, 2- (O-benzoyloxime) (Irgacure (registered trademark) OXE01, manufactured by BASF Japan Kagaku Co., Ltd.) have.

As the resin binder of the infrared transmitting layer 2, various known additives such as a photosensitizer, a dispersant, a surfactant, a stabilizer, and a leveling agent may be included.

[Formation of infrared transmission layer 2]

The method of forming the infrared transmitting layer 2 is not particularly limited in the present embodiment. However, in the resin binder containing the uncured resin of the photosensitive resin, a colored photosensitive resin containing three or more predetermined coloring pigments By the composition, the infrared transmitting layer 2 can be formed. The colored photosensitive resin composition may further contain a solvent for adjusting the application suitability when the resin composition is applied on the surface of the transparent substrate 1. As the solvent, for example, one or more kinds of propylene glycol monomethyl ether, propylene glycol monomethyl ether acetate, ethyl cellosolve, 3-methoxybutyl acetate and the like can be used.

As the colored photosensitive resin composition containing the coloring pigment and the uncured resin of the photosensitive resin as described above, or the uncolored product of the colored pigment and the photosensitive resin, conventionally, a colored resist adjusted as a color filter may be used.

The method of applying the colored photosensitive resin composition on the surface of the transparent substrate 1 can be carried out by a known coating method such as a spin coating method, a roll coating method, a die coating method, a spray coating method and a bead coating method can do.

After the colored photosensitive resin composition is applied on the surface of the transparent substrate 1, the colored photosensitive resin composition is patterned through a predetermined process such as exposure, development, and baking using photolithography, The infrared transmitting layer 2 having a predetermined pattern can be formed.

[Shielding Layer (3)]

The shielding layer 3 in the embodiment shown in Fig. 1 is provided on one side of the transparent substrate 1 facing the touch panel 20 and the display panel 30 side, that is, on the second side of the transparent substrate 1 S2 in the opaque region A2. More specifically, the shielding layer 3 is formed in the entire region except the portion of the infrared transmission window 4 in the opaque region A2. By the shielding layer 3 and the infrared transmitting layer 2, the opaque region A2 is formed as an opaque region with respect to visible light. The shielding layer 3 is provided with a wiring or a control circuit disposed on the outer periphery of the position detection region at the center of the touch panel 20 or a display panel 30 arranged on the periphery of the touch panel 20 together with the infrared transmission layer 2 shielding visible light. It is impossible to visually observe these wirings and control circuits by hiding the wirings and control circuits disposed on the outer peripheral portion of the display region in the center of the display region. Thereby, the shielding layer 3 has a function of preventing the appearance of the display device using the touch panel 20 or the display panel 30 from being impaired.

The shielding layer 3 is required to shield at least visible light so that the necessary shielding property for the visible light as the opaque region A2 can be improved by the shielding property of the shielding layer 3 and the visible light portion of the infrared transmitting layer 2 It can be realized. Therefore, the light shielding property of the shielding layer 3 alone can be as small as that, or the film thickness can be made thinner. However, in the case of expressing black in the case of expressing black, the shielding layer 3 can contain a black pigment which is excellent in light-shielding property, in addition to carbon black, even though it is thinner than carbon black like titanium black. Therefore, the shielding layer 3 can obtain a sufficient shielding property against visible light even if the film thickness is thin. For example, the shielding layer 3 can easily realize a light shielding property of an optical density OD 5.0 (transmittance of one hundred thousandths of one) with a film thickness of 1.5 탆. Shielding property against the visible light as the opaque region A2, that is, the light shielding property may be the one obtained by the shielding layer 3 and the infrared transmitting layer 2. [ Normally, the light shielding properties of both the shielding layer 3 and the infrared transmitting layer 2 depend on the required specifications and the expressive color. However, the light transmittance is preferably 3% or less (optical density OD is 1.5 or more) , It is preferable that the transmittance is 1% or less (optical density OD 2.0 or more), and more preferably 0.01% or less (optical density OD 4.0 or more) in transmittance.

However, as in the present embodiment, the shielding layer 3 itself containing the black pigment in particular has a problem of deterioration of adhesion with the translucent substrate 1, particularly the chemically tempered glass translucent substrate 1 under high temperature and high humidity Lt; / RTI > However, by interposing the infrared transmitting layer 2 therebetween all the time, it is possible to prevent the problem of deterioration of the adhesiveness under high temperature and high humidity even in the opaque area A2 in which the black pigment is expressed by black, Can be formed by the transparent layer (2). Since the shielding layer 3 is always laminated on the transparent substrate 1 via the infrared transmitting layer 2, when the blackening is expressed solely by the shielding layer 3 as in the present embodiment, The reflectance of the layer 3 is increased, and in particular, a phenomenon that the contrast is damaged under sunlight or the like can be improved by the presence of the infrared transmitting layer 2. The infrared transmitting layer 2 is formed on the side of the transparent substrate 1 which faces the shielding layer 3 and on the side where the shielding layer 3 is formed and the infrared transmitting window 4 ) Are also included. As a result, the appearance color of the opaque region A2 can be made into one color including the portion of the infrared transmission window 4, so that the infrared transmission window 4 can be provided in a design free from discomfort.

The shielding layer 3 is composed of a layer containing a colored pigment, which may contain a black pigment, in a resin binder containing a cured product of a photosensitive resin. The method for forming the shielding layer 3 is not particularly limited. For example, a colored photosensitive resin composition containing a coloring pigment and an uncured resin of a photosensitive resin is coated on the surface of the transparent substrate 1, Called photolithography, in which the photoresist layer is exposed and developed in the pattern of the photoresist layer. In the present embodiment, the shielding layer 3 is formed by photolithography.

The shielding layer 3 formed by photolithography using the photosensitive resin composition as described above is thinner than the screen printing method and has a thickness of 5 탆 or less, more preferably 1.5 탆 or less and 3 탆 or less And the shielding layer 3 and the infrared transmitting layer 2 which are formed at the boundary between the forming portion and the non-forming portion of these two layers in the laminated portion where the shielding layer 3 and the infrared transmitting layer 2 are overlapped with each other, The thickness of the rim portion can be reduced by the total thickness of the film. Specifically, the thickness of the shielding layer 3 formed by photolithography using the photosensitive resin composition can be 0.2 to 3 탆. Even when the shielding layer 3 is made to have the same color as that of the infrared transmitting layer 2, for example, black, the light shielding property as the opaque region A2 can be improved by the fact that both of the shielding layer 3 and the infrared transmitting layer 2 The necessary shielding properties can be obtained as a whole when the thickness of the shielding layer 3 is 0.5 mu m or more. However, when the shielding layer 3 is made black, it is preferable that the thickness of the shielding layer 3 is 0.5 m or more in consideration of the black light shielding property.

In the present embodiment, the shielding layer 3 is formed in a pattern in the opaque region A2, but the method of forming the pattern is not limited to the photolithography method, but the shielding layer 3 and the infrared transmitting layer 2, Other pattern formation methods such as the above-mentioned screen printing method, inkjet printing method, and the like may be used as long as the problem of the step difference due to the total thickness of the edge portion can be solved. However, as described above, in comparison with the screen printing method, the photolithography method can be applied to one type of the preferable forming method in view of the fact that the problem of the step difference can be made thin enough to effectively solve the problem, to be.

[Coloring Pigment]

As the colored pigment used in the shielding layer 3 in the present embodiment, both a black pigment showing black and a colored pigment other than black can be used. As the black pigment showing black, for example, titanium black (low-order titanium oxide, titanium oxynitride, etc.), carbon black and the like can be used. Titanium black has a higher light shielding property with respect to visible light at the same concentration and the same film thickness as those of carbon black, and in the case of the same light shielding property, the film thickness can be made thinner and the step can be made smaller. . As the color pigments other than black, for example, red pigments, yellow pigments, blue pigments, green pigments, and purple pigments can be used. The content of the coloring pigment depends on the light shielding property and the color for the visible light which is required, but the pigment concentration, which is expressed as a percentage of the amount of the coloring pigment to the total solid content of the shielding layer 3 including the coloring pigment and the resin binder, For example, about 10 to 70%. It is preferable that the pigment concentration is as high as possible in order to ensure sufficient light shielding.

[Photosensitive resin]

As the above-mentioned photosensitive resin which is a resin component of a resin binder which disperses and holds a coloring pigment, a resin (listed in column) may be used as the infrared transmitting layer (2). For this reason, a further explanation will be omitted.

[Visible information (6)]

1, the front protective plate 10 for a display according to the present embodiment is provided with opaque regions A2 in which the infrared transmitting layer 2 and the shielding layer 3 are formed, Logo mark is formed. In the present embodiment, characters, symbols, shapes, and the like for operation explanation can be set as the visible information 6 in addition to the product logo mark in the opaque area A2. The visible information 6 may be formed as a pattern of a non-formed portion in which the non-molded portion of the infrared transmitting layer 2 and the non-molded portion of the shielding layer 3 are arranged to overlap with each other, or the infrared transmitting layer 2 and the non- It can be formed as a layer having a color different from that of the infrared transmitting layer 2 or the shielding layer 3 between the substrates 1. The transparent layer 2 or the shielding layer 3 is formed by using the same material and method as the infrared transmitting layer 2 or the shielding layer 3 to form the visible information 6 ) Can be formed. Or the non-forming portion of the infrared transmitting layer 2 and the non-forming portion of the shielding layer 3 are arranged on the other side of the shielding layer 3 or the infrared transmitting layer 2 ) And the shielding layer 3 may be formed of a metal thin film such as aluminum formed by a vapor deposition method such as vapor deposition or sputtering.

In the present embodiment, the visible information 6 formed in the opaque area A2 needs to be opaque to the same extent as the light shielding by the infrared transmitting layer 2 and the shielding layer 3, none. For example, visible information (6) such as a character or a symbol for an operation explanation illuminated on the back may be displayed so that even in a dark place. In the present embodiment, unless hindering the wiring or the like disposed on the outer periphery of the touch panel 20 or the display panel 30 is hindered, for example, the non-formation portion of the infrared transmission layer 2, The outer contour is partitioned by the infrared transmitting layer 2 or the shielding layer 3 as in the visible information 6 formed as a pattern of the non-formed portion in which the unformed portions of the layer 3 are arranged to overlap with each other As in the visible information 6 that can be recognized, a region where the light shielding property is smaller than that of the infrared transmitting layer 2 is present in a part, such as a typically transparent portion, in which the visible information 6 has a higher transmittance than the surrounding portion You can.

[Modifications]

The front cover 10 for a display device of the present embodiment may take other forms other than the above-described forms. Hereinafter, a part thereof will be described.

[Integration with touch panel function]

1, the front cover 10 for a display device includes a translucent substrate 1, an infrared transparent layer 2, and a shielding layer 3, and the infrared transparent window 4, And the visual information 6 is also provided. However, in the present embodiment, other constituent elements may be provided. An example of this is integration with the touch panel function. For example, a transparent electrode for a touch panel may be provided on the transparent substrate 1, and the transparent substrate 1 may be used as a substrate for a touch panel. In the case where the integration with the touch panel function integrates a part of the functions required as the touch panel, the number of parts is reduced and the effect of reducing the thickness is obtained. More preferably, all necessary functions as a touch panel are integrated.

The front cover 10 for a display device, which integrates all functions required as a touch panel, may be referred to as a touch panel. The front shield plate 10 for a display device, which integrates some of the necessary functions as a touch panel, may be referred to as a member for a touch panel. For example, in a case where a part of the touch panel function is integrated, at least the transparent electrode is integrated with the front cover 10 for the display device in a system in which the position detecting transparent electrode is required as the touch panel function. Conventionally, various methods for detecting the position of the touch panel have been known. In the position detecting method in which the transparent electrodes are formed in two layers, at least one layer, more preferably two layers, ). Hereinafter, an example of the integration of the touch panel functions will be described with reference to the embodiment of Fig.

3, the transparent electrode 8 for the touch panel is formed on the second surface S2 side on the side where the infrared transmitting layer 2 and the shielding layer 3 are formed, And a wiring 9 are formed. Here, the transparent electrode 8 for the touch panel is a projection type electrostatic capacitance type electrode. More specifically, the shielding layer 3 has one surface S3 adjacent to the infrared transmitting layer 2 and the other surface S4 located on the opposite side to the one surface S3, and the other surface of the shielding layer 3 The transparent electrode 8 for position detection of the touch panel is formed on the side of the side surface S4 and the portion of the opaque region A2 having the infrared transmitting layer 2 and the shielding layer 3 from the display region A1 And is electrically connected to the opaque wiring 9 disposed in the region overlapping with the shielding layer 3 in the opaque region A2. In the sectional view of Fig. 3, the illustration of the infrared transmission window 4 is omitted for the sake of avoiding the redundancy in the drawing.

4A and 4B schematically show the pattern shape of the transparent electrode 8, in the plan view of FIG. 4A and FIG. 4B. In the example shown in the drawing, a plurality of first transparent electrodes 8a extending in a first direction (vertical direction in the drawing) and a plurality of second transparent electrodes 8b extending in a second direction The second transparent electrodes 8b are formed on the same side of the transparent substrate 1, that is, on the second surface S2 side. 4 (a) shows the infrared transmission window 4 and the visible information 6 provided in the opaque area A2. In the pattern of the transparent electrode 8 of the projection type capacitance type of this kind, various patterns are known, and therefore, a brief description will be given here. 4, one first transparent electrode 8a is composed of a plurality of large-area portions 8aL having a rhombic shape and a plurality of large-area portions 8aL adjacent to each other, as shown in a partial plan view of FIG. 4 (b) And a lead-out portion (not shown) for extending to the outer periphery of the position detection region and electrically connecting to the wiring 9. Likewise, one second transparent electrode 8b is also constituted by a plurality of rhombic shape facing portions, a connecting portion connecting the adjacent facing portions, and a take-out portion. 4 (a), only the opposite surface portions of the respective transparent electrodes 8a and 8b are shown, and the illustration of the connecting portion and the taking-out portion is omitted. The large-area portion of the transparent electrode 8a and the large-area portion of the transparent electrode 8b are formed on the same plane. Each of the connecting portions is formed as a continuous layer on the same plane on the transparent electrode 8a with the facing portion 8aL and the connecting portion 8aC as shown in Fig. 4 (b). On the other hand, in the transparent electrode 8b, if the facing portion and the connecting portion are formed as a continuous layer on the same plane, the insulation with the transparent electrode 8a can not be ensured. The overcoat layer 7b is formed as an insulating layer in a portion intersecting with the transparent electrode 8a (specifically, the portion where the connection portion 8aC of the transparent electrode 8a is present) The connection portion of the transparent electrode 8b is formed to secure the above insulation.

3, the display panel 10 includes the transparent layer 2 and the shielding layer 3 on the second surface S2 of the transparent substrate 1, The overcoat layer 7a is formed over the application area A1 and the opaque area A2 so that the step difference of the edge part formed by the infrared transmission layer 2 and the shielding layer 3 formed with a film thickness of 5 mu m or less as a total of two layers . In addition, on the surface of the overcoat layer 7a, a facing portion, a connecting portion, and a taking-out portion of the first transparent electrode 8a are formed, and the second transparent electrode 8b is formed only in the facing portion and the blowing portion. After the transparent electrodes 8a and 8b are formed and the overcoat layer 7b is partially formed as an insulating layer at the intersection of the transparent electrode 8a and the second electrode 8b, The connection portion of the electrode 8b extends over the over-facing portion of the adjacent transparent electrode 8b via the overcoat layer 7b. The first transparent electrode 8a and the second transparent electrode 8b extend from the central position detection area to the overlapping area of the shielding layer 3 and are opaque per se and are visible 9). The wiring 9 is shown only for the first transparent electrode 8a in the figure. An overcoat layer 7c is formed on the substantially entire surface of the second surface S2 on the side where the wiring 9 of the transparent substrate 1 is formed after the wiring 9 is formed and the first transparent electrode 8a And the surface of the second transparent electrode 8b as the front protective plate 10 for the display device are protected from scratches and the like. However, the overcoat layer 7c is not formed in the portion where the wiring 9 is connected to the control circuit via the flexible printed wiring board (FPC), and the wiring 9 is exposed.

For the overcoat layer 7a, the overcoat layer 7b and the overcoat layer 7c, a transparent resin such as an epoxy resin, an acrylic resin, a polyimide resin or the like can be used. As a concrete example, a thermosetting epoxy resin Etc. may be used. Further, a photosensitive resin or the like referred to as the infrared transmitting layer 2 or the shielding layer 3 may be used. In the case of a photosensitive resin, a photolithography method can be used for forming a part. The overcoat layer 7b, which serves as an insulating layer at the intersection of at least the first transparent electrode 8a and the second transparent electrode 8b in each overcoat layer 7, is transparent and has electrical insulation. These overcoat layers may be formed by the same coating method as that of the infrared transmitting layer 2 or the shielding layer 3.

(Indium Tin Oxide), IZO (Indium Zinc Oxide), AZO (Aluminum Zinc Oxide), and Aluminum Zinc Oxide) may be added to the first transparent electrode 8a and the second transparent electrode 8b. Or the like can be used as the transparent conductive thin film.

As the wiring 9, for example, a metal such as silver, gold, copper, chromium, platinum, aluminum, palladium, or molybdenum may be used. For example, a metal layer of an alloy (also referred to as APC) comprising silver, palladium and copper may be used as the wiring 9, and the metal layer may be patterned by photolithography after film formation by sputtering .

As described above, in the present embodiment, the wiring 9, which is provided around the central position detection area as a touch panel and is visible to the naked eye itself, is in the region overlapping the shielding layer 3 in a plan view So that there is no case of damaging the appearance when applied to a display device. In addition, by forming the infrared transmitting layer 2 between the transparent substrate 1 and the shielding layer 3, there is a problem that the adhesion of the shielding layer 3 is lowered at a high reflectivity or under high temperature and high humidity. The problem of the step difference due to the total of the two layers of the shielding layer 3 and the infrared transmitting layer 2 is also improved and the transparent electrode is extended to the portion of the shielding layer 3 laminated on the infrared transmitting layer 2 It is possible to reduce the possibility of disconnection. It also has a touch panel function, which is also effective in reducing the number of parts and weight.

[C] Display device:

The display device according to the present embodiment includes the above-described front panel shield 10 for a display device and a display panel. The display device according to the present embodiment may be provided with a touch panel when the front cover 10 for the display device does not have a touch panel function. The display device according to the present embodiment includes the above-described front panel protection plate 10 for a display device, a touch panel, and a display panel, and the touch panel is disposed around the position detection transparent electrode The opaque wiring overlapped with the shielding layer 3 of the front protective plate 10 for the display device may be arranged so that it can not be seen visually from the side of the front protective plate 10 for the display device. Alternatively, the display device according to the present embodiment may be configured to include a front panel protection plate 10 for a display device having a transparent electrode for a touch panel and an opaque wiring, and a display panel.

5 is an embodiment of a display device according to the present invention. The display device 100 shown in Fig. 5 includes, in order from the observer V side on the upper side in the drawing, a front panel 10 for the display device, (20), and a display panel (30). In the present embodiment, the front cover 10 for the display device is the above-described front cover 10 for the display device. More specifically, the front cover 10 for the display device does not integrate the touch panel functions. The touch panel 20 schematically shows the wiring 9 and the transparent electrode 8. An infrared-use component such as a seal sensor is provided as a component of the display device 100 on the other side (downward in the drawing) of the infrared transmission window 4 provided on the display front cover 10, The illustration of the parts for infrared use is omitted.

Typically, the touch panel 20 is a projection-type capacitive touch panel capable of multi-touch (multi-point simultaneous input). However, the touch panel 20 may be a surface-type capacitance type, a resistive film type, Or any of various known position detection type touch panels including a position detection method that does not require a transparent electrode. The touch panel 20 has any opaque components such as a wiring 9, a control circuit, and a connector for electrically connecting them to the outer periphery of the central position detection area. These opaque components are placed on the shielding layer 3 of the opaque area A2 of the display front protective plate 10 in such a manner that the touch panel 20 and the front cover for the display device 10 are disposed. This makes it possible to prevent the opaque components such as the wirings 9 from damaging the appearance of the display device 100.

The display panel 30 is typically a liquid crystal display panel or an electroluminescence (EL) panel, but may be a display device using an electronic paper panel, a cathode ray tube, or various known display panels.

By using the display device 100 having the above-described configuration, it is possible to design a product in which the infrared transmission window 4 is embedded in the front cover 10 for the display device, and at the same time, Various components such as wirings, connectors, and control circuits, which are unnecessary in the display content itself existing in the outer periphery of the outer periphery or the display area of the display panel 30, are hidden, thereby preventing the outer appearance from being damaged .

[Modification of display device]

In the display device 100 according to the present embodiment, the front panel shield 10 for the display device has a form in which the functions of the touch panel are not integrated at all. However, in the present embodiment, the front protective plate 10 for the display provided in the display device 100 may have a part or all of the touch panel functions integrated with each other. In this case, in the case of using the front cover 10 for the display device in which all of the touch panel functions are integrated, it is not necessary to provide an independent touch panel 20 and the front cover 10 for the display device ), And a display panel 30, as shown in Fig. In this configuration, the wiring, the connector, the control circuit, and the like in the outer peripheral portion of the display panel 30 can be hidden.

In addition, the touch panel to be incorporated has a transparent electrode, and the transparent electrode includes two layers of a first transparent electrode 8a and a second transparent electrode 8b insulated from each other, In the case where the two layers are formed on different substrates from each other, either one of the substrates is also used as the translucent substrate 1 of the front cover 10 for a display device, And the other transparent electrode and the board are integrated as a touch panel constituting member separate from the display front panel protecting plate 10 and the display panel 30 so that the display device 100 ) Can also be configured. Any configuration may be used to integrate the front panel shield 10 for a display device with the touch panel function, or a configuration suitable for various conditions such as manufacturing facilities and assembly processes that can be used.

[D] Application:

The use of the front shielding plate 10 and the display device 100 according to the present embodiment is not particularly limited. For example, it is a mobile phone such as a smart phone, a portable information terminal such as a tablet PC, a personal computer, a car navigation system, a digital camera, an electronic notebook, a game machine, a automatic ticket machine, an ATM terminal, and a POS terminal.

[Operation and effect of the present embodiment]

As described above, according to the present embodiment, the transparent substrate 1 and the shielding layer 3 formed on the opaque region A2 on at least one surface side of the transparent substrate 1, at least the visible light is shielded, The portion constituting the window 4 is composed of a shielding layer 3 formed as a non-forming portion and an infrared transmitting layer (not shown) laminated on a portion of the opaque region A2 on the one surface side including the unformed portion of the shielding layer 3 2), and has an infrared transmitting layer (2) shielding visible light and transmitting infrared light. The infrared transmitting layer (2) has a shielding layer (3) including the unformed portion serving as an infrared transmitting window (4) And is formed in the entire region between the substrates 1. According to such a configuration, when the front protective plate 10 for a display device is observed on the other surface side of the transparent substrate 1, the infrared transparent window 4 is observed with the infrared transparent layer 2 covered The infrared transmission window 4 can be made less conspicuous. Further, since there is no need to provide an infrared transmission window in the case of the display apparatus 100, it is possible to make the case of the display apparatus 100 correspond to a wider design. Further, since it is not necessary to provide the infrared transmission window in the case of the display apparatus 100, the appearance design is not damaged.

In addition, the infrared transmitting layer 2 can be made to have a pigment different from the shielding layer 3, and as a result, it is easier to adjust the color taste as compared with the shielding layer 3. That is, when the other surface side of the transparent substrate 1 is to be observed, the infrared transmitting layer 2 is arranged closer to the observer side than the shielding layer 3, whereby the opaque region A2 It is easy to adjust the color taste of the reflection color of Similarly, in the infrared transmitting layer 2, the contained pigment can be made different from the shielding layer 3, and as a result, compared with the case where the light shielding effect on the opaque region A2 is realized only by the shielding layer 3 , The reflectance can be suppressed to a low level. As a result, it is possible to suppress reflection of external light and display an image from the display device 100 with high contrast.

Particularly, the shielding layer 3 contains a colored pigment which may contain a black pigment in a resin binder containing a cured product of the photosensitive resin, and the infrared transmitting layer 2 contains a colored pigment as a cured product of the photosensitive resin And the coloring pigments of the infrared transmitting layer 2 are different in color from each other and contain at least three kinds of coloring pigments other than black, the three kinds of coloring pigments in the infrared transmitting layer 2 By adjusting the ratio of the coloring pigments to each other, it is possible to adjust the color taste of the reflection color in the opaque region A2 and the reflectance in the opaque region A2 to a higher degree of freedom.

In addition, according to the present embodiment, the total thickness of the infrared transmitting layer 2 and the shielding layer 3 can be made thin, and the step of the rim portion caused by these film thickness can be reduced. Therefore, the shielding layer 3 has one surface S3 adjacent to the infrared transmitting layer 2 and the other surface S4 located on the opposite side to the one surface S3, and the other surface S4 of the shielding layer 3 The transparent electrode 8 for position detection of the touch panel is formed on the S4 side and the transparent electrode 8 extends from the display region A1 to the opaque region A2 and the opaque region 8, It is possible to reduce the possibility that the transparent electrode 8 for position detection of the touch panel 20 is disconnected at the stepped portion when the transparent electrode 8 for position detection of the touch panel 20 is formed by the sputtering method or the like when the wiring 9 is electrically connected to the non- .

According to the present embodiment, the infrared transmitting layer 2 is interposed between the transparent substrate 1 and the shielding layer 3. As a result, it is possible to solve the problem that the adhesion between the transparent substrate 1 and the shielding layer 3 is lowered. Particularly, in the above-described embodiment, the infrared transmitting layer 2 is disposed between the transparent substrate 1 and the shielding layer 3 adjacent to the transparent substrate 1 and the shielding layer 3. According to this embodiment, it is possible to sufficiently secure the adhesion of the infrared transmitting layer 2 and the shielding layer 3 under high temperature and high humidity, while sufficiently securing the adhesion of the infrared transmitting layer 2 and the transparent substrate 1 under high temperature and high humidity have. Therefore, the lowering of the adhesion of the shielding layer 3 and the transparent substrate 1 under high temperature and high humidity can be more effectively improved through the infrared transmitting layer 2.

According to the display device 100 of the present embodiment, the touch panel 20 further includes a touch panel 20 between the front cover 10 for the display device and the display panel 30, A transparent electrode 8 extending from an area overlapping with the opaque area A2 to an area overlapping with the opaque area A2 and an opaque wiring 9 disposed in an area overlapping the shielding layer 3, And is electrically connected to the opaque wiring 9 in the area overlapping with the opaque wiring 9. According to this embodiment, it is possible to provide an observer who observes the display light from the display panel 30 from the observer side, the opaque wiring 9 is shielded by the shielding layer 3 of the opaque area A2 of the display front cover plate 10, It seems to be overlapped and hidden. As a result, the appearance of the display device 100 can be prevented from being damaged by the opaque wiring 9.

Example

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

[Example 1]

As the translucent substrate, a chemical tempered glass having a thickness of 0.5 mm was used, and an infrared transmitting layer was formed on the outer peripheral portion of one side used as the side of the chemically tempered glass. The infrared transmitting layer was formed by patterning a composition containing a pigment and a resin binder comprising a photosensitive resin curable by ultraviolet irradiation, by photolithography to have a film thickness of 2.5 탆. Three kinds of organic color pigments represented by red, yellow, and blue, respectively, were added to the resin binder without containing a black pigment such as titanium black or carbon black. That is, the three colors were mixed to display black. The resin binder used was a resist for a color filter colored layer (colored resist) using an acrylic resin.

Red pigment: Pigment Red 254 (PR254) based on diketopyrrolopyrrole,

Yellow Pigment: Pigment Yellow 139 (PY139) of isoindolin system

· Blue pigment: Pigment Blue PB15: 6 (PB15: 6) based on copper phthalocyanine.

Yellow pigment: Blue pigment = 35: 35: 30 (mass ratio).

Subsequently, on the surface of the infrared transmitting layer, a shielding layer having a non-forming portion as a portion to be an infrared transmitting window was formed. This shielding layer was formed by patterning a composition containing a black pigment and a resin binder containing a photosensitive resin curable by ultraviolet irradiation by photolithography to have a film thickness of 0.9 m. The black color pigment was blackened by containing carbon black. The resin binder was a black resist for a black stripe of a color filter using an acrylic resin. The total thickness of the infrared transmitting layer and the shielding layer was 3.4 mu m.

[Example 2]

A front panel protection plate for a display device was fabricated in the same manner as in Example 1 except that the thickness of the infrared transmission layer in Example 1 was reduced to 2.1 占 퐉 and the total thickness of the infrared transmission layer was 3.0 占 퐉.

[Example 3]

The procedure of Example 1 was repeated except that the thickness of the infrared transmitting layer was reduced to 1.1 占 퐉 and the thickness of the shielding layer was increased to 1.2 占 퐉 so that the total film thickness was 2.3 占 퐉 A front cover for a display device was manufactured.

[Example 4]

The procedure of Example 1 was repeated except that the thickness of the infrared transmitting layer was reduced to 0.5 占 퐉 and the thickness of the shielding layer was increased to 1.4 占 퐉 so that the total film thickness was 1.9 占 퐉 A front cover for a display device was manufactured.

[Example 5]

The procedure of Example 1 was repeated except that the thickness of the infrared transmitting layer was reduced to 0.3 占 퐉 and the film thickness of the shielding layer was increased to 1.5 占 퐉 so that the total film thickness was 1.8 占 퐉 A front cover for a display device was manufactured.

[Comparative Example 1]

In Example 1, the material for forming the infrared transmitting layer was changed to a transparent resist containing the same resin binder and also including a black pigment and no coloring pigment, so that a transparent resin having a thickness of 1.5 占 퐉 Strata. Otherwise, a front shielding plate for a display device having a total thickness of 3.0 mu m with the shielding layer was produced in the same manner as in Example 1. [

[Comparative Example 2]

A front panel protection plate for a display device was prepared in the same manner as in Example 1 except that the formation of the infrared transmission layer was omitted and only the shielding layer was formed to have a thickness of 1.5 탆.

[Comparative Example 3]

In Example 1, the formation of the infrared transmitting layer was omitted, the material for forming the shielding layer was changed to black ink for screen printing containing carbon black as a black pigment, screen printing was carried out, Layer was formed on the entire surface of the substrate.

[Performance evaluation method]

The following optical properties and adhesion at high temperature and high humidity were evaluated.

[Optical characteristics]

Optical characteristics were measured by using a microscopic spectroscopic photometry apparatus in the following items.

1) Optical Density (OD):

The light shielding property against the transmitted light in the entire visible light region where only the infrared transmitting layer or the infrared transmitting layer and the shielding layer are laminated was evaluated by the optical density. This optical density is expressed by the ratio of the intensity Iin of the incident light perpendicularly incident on the portion where the infrared transmission layer alone (the infrared transmission window portion) or the portion where the infrared transmission layer and the shielding layer are laminated and the intensity Iout of the transmitted light transmitted vertically, log ₁₀ (Iin / Iout) ". When the OD value is 4.0, the visible light transmittance becomes 1/10000. In the portion where the infrared transmitting layer and the shielding layer are laminated, if the OD value is 4.0 or more, it can be sufficiently satisfied as a black opaque region. In the configuration in which a transparent resin layer was formed instead of the infrared transmitting layer, a portion of only the transparent resin layer or a laminated portion of the transparent resin layer and the shielding layer was measured. In this embodiment, by using the microscopic spectroscopic light-measuring device, the spectroscopic characteristics are measured for the incident light vertically incident from the translucent substrate side and the transmitted light transmitted through the front cover for the display device, and the spectroscopic characteristics of JIS-Z8701 The optical density was calculated using the brightness Y in the XYZ colorimetric system.

2) Reflectance:

When the incident light incident from the side of the transparent substrate on the side where the shielding layer formed on this side exists is the interface between the shielding layer and the transparent substrate or the infrared transmitting layer between the transparent layer and the transparent substrate, The ratio of the intensity Iref of the reflected light to the intensity Iin of the incident light, (Iref / Iin (Iin / Iin)) is a ratio of the intensity Iref of the reflected light to the intensity Iin of the incident light at a ratio of the intensity of the reflected light reflected by the interface between the shielding layer and the transparent resin layer to the light- ) × 100. The influence of the reflected light generated at the interface between the light-transmitting substrate and the air can be ignored, as in the case of the reflection chromaticity shown in 2) above. When the infrared transmission layer is present and the optical density is small, reflected light from the interface between the infrared transmission layer and the shielding layer is also partially included and measured. In the configuration in which the transparent resin layer was formed instead of the infrared transparent layer, the reflected light at the interface between the transparent resin layer and the shielding layer was measured. In this embodiment, by using the microscopic spectroscopic light-measuring device, the spectroscopic characteristics were measured for the incident light vertically incident from the translucent substrate side and the reflected light toward the front cover for the display device, and the spectroscopic characteristics were measured according to JIS-Z8701 The reflectance was calculated using the brightness Y in the comparable XYZ color system.

[Adherence under high temperature and high humidity]

The adhesion of the shielding layer to the light-transmitting substrate under high temperature and high humidity was measured by setting the test piece at a temperature of 60 캜 and a relative humidity of 95% RH for a maximum of 400 hours and measuring the initial value at the start of the test, The adhesion was measured and evaluated by the following. When an intervening layer such as an infrared transmission layer is interposed between the shielding layer and the transparent substrate, the adhesion between the intervening layer and the shielding layer as a laminate is evaluated.

Specifically, the adhesion was evaluated in accordance with a checkerboard tape method of JIS K5400 (1990). That is, on the shielding layer of the test piece, a nick of 1 mm width was cut out with a cutter knife, and 100 check squares made of a square having a size of 1 mm were made. On this check mark, a cellophane adhesive tape (manufactured by Nichiban Co., Ltd.) 1 to 2 minutes after attaching, one end portion of the cellophane adhesive tape was held and held at right angles to the test piece surface and instantly peeled off. The adhesiveness was evaluated from the state of the checkerboard surface by the evaluation score.

The evaluation score is determined based on the following criteria, with 10 being the best score and 0 being the worst score.

10 points: Each slit is thin, both ends are smooth, and there is no peeling of the check mark scale.

8 points: There is a slight peeling at the intersection of the nicks, but there is no peeling of the check mark scale, and the area of the defect area is within 5% of the whole check mark scale.

6 points: There is exfoliation at the intersection with both sides of the slit, and the area of the slit is 5 to 15% of the whole grid.

4 points: The state that the width of the exfoliation due to the nicks is wide and the area of the defects is 15 to 35% of the whole check mark scale.

2 points: The state in which the width of the peeling by the nicks is wider than 4 points and the area of the defects is 35 to 65% of the whole grid.

0 point: The area of the defective area is 65% or more of the whole grid.

In Table 1, the evaluation of the adhesion property is as follows. &Quot; A " indicates that no decrease in adhesion (evaluation score) is not recognized even after 400 hours elapsed, and " , &Quot; indicates that the adhesiveness (evaluation score) is lowered after 100 hours elapsed, and " X " indicates that the adhesiveness (evaluation score) has already been lowered even after 20 hours elapsed. Since the performance of Comparative Example 2 deteriorates after lapse of 20 hours, the initial performance can be maintained after at least 20 hours have elapsed.

[Performance evaluation result]

Table 1 shows the main contents of the layer structure on the light-transmitting substrate of the examples and the comparative example and the performance evaluation results.

In Example 1, even when the total thickness of the infrared transmitting layer and the shielding layer is 3.4 占 퐉, which is 5 占 퐉 or less, which can improve the problem of the step difference, the light shielding property is 5.0 as the optical density OD And a reflectance of 3.0% or less can be realized. As described above, the optical performance as an opaque region by the infrared transmitting layer and the shielding layer as the basic performance can be satisfied. As the coloring pigment, black pigments such as carbon black and titanium black are not used for the portion where the shielding layer does not exist on the translucent substrate and only the infrared transmitting layer serves as the infrared transmitting window, and three kinds of red, The black color is expressed by a combination of. This portion was 2.5 mu m in film thickness, and the light shielding property that the optical density OD was 2.0 could be secured. The transmittance of the infrared transmitting layer to infrared light was 50% or more at a wavelength of 800 nm and 90% or more at a wavelength of 850 to 1300 nm. The adhesion of the shielding layer under high temperature and high humidity was 10 points even after the test time of 400 hours, and no deterioration was observed with respect to the initial state, and an adequate performance (evaluation "?" In Table 1) was obtained.

In Examples 2 to 5, the film thickness of the infrared transmitting layer was reduced in this order so that the optical density OD 5.0 could be maintained for Example 1, and the film thickness of the shielding layer was increased correspondingly to be. In any of the embodiments, the film thickness of 3.0 탆 or less can be realized while maintaining the optical density OD 5.0. However, in Example 5 in which the thickness of the infrared-transmitting layer was the minimum at 0.3 m, the reflectivity increased to 3.65%. This indicates that it is preferable to increase the optical density of the infrared transmitting layer in order to suppress the reflectance to a low level. For example, if a reflectance of 3.5% or less is desired and a product having a lower reflectance is desired, in order to make the thickness of the infrared transmitting layer 0.5 mu m or more and the reflectance small, the thickness of the infrared transmitting layer is preferably 1.5 mu m Or more.

On the other hand, the adhesion of the shielding layer to the translucent substrate under high temperature and high humidity was evaluated in both of Examples 2 to 5, even when the thickness of the infrared transmitting layer was as thin as 0.3 占 퐉. 10, and no deterioration with respect to the initial state was confirmed, and sufficient performance (evaluation "?" In Table 1) was obtained.

In Comparative Example 1 in which the transparent resin layer excluding the colored pigment was interposed in place of the infrared transmittance layer in the reflectance, the adhesion was not deteriorated up to 400 hours in the same manner as in each of Examples, ? "), An improvement effect on the adhesion reduction was confirmed, and the optical density OD was also maintained at 5.0. However, the reflectance exceeded 4% at 4.83%. This indicates that, in order to suppress the reflectance to a low level, it is not effective to simply interpose a resin layer between the shielding layer and the translucent substrate, but to interpose a colored infrared transmission layer therebetween.

Comparative Example 2 of only the shielding layer is made of a resist for black matrix of a color filter in which black is represented by black pigment. However, even when the thickness is as small as 1.5 탆, a light shielding property with an optical density OD value of 5.0 is obtained. And the adhesion has already started to deteriorate at a test time of 20 hours, and the adhesion is not satisfactory (evaluation "x" in Table 1).

In Comparative Example 3, only the shielding layer formed by the ink for screen printing in which black is represented by black pigment, there is no problem in optical performance and adhesion of the optical density OD and reflectivity. However, the film thickness for the shielding layer is as thick as 6.0 m, There is a problem of step difference. Of course, the shielding layer of this ink is shielding against infrared light, and if the infrared transmission window is provided as a non-forming portion, the portion becomes the transparency of the translucent substrate, which is not preferable as a product design.

Claims (9)

A front shield plate for a display device, comprising: a central display region; an opaque region formed on an outer periphery of the display region and shielding visible light; and an infrared transmission window for transmitting infrared light to a part of the opaque region,
A light-
A shielding layer formed on the opaque region on at least one surface side of the first surface of the transparent substrate and the second surface opposite to the first surface, the shielding layer at least covering the visible light, A shielding layer formed as an active portion,
And an infrared transmitting layer which is laminated on a portion of the opaque region on the side of the one surface including the unformed portion of the shielding layer and which shields visible light and transmits infrared light,
Wherein the infrared transmitting layer comprises at least a blue pigment and a red pigment and is formed as a continuous layer on the entire surface of the entire region between the shielding layer and the transparent substrate including the non- Forward facing shield. The method according to claim 1, wherein the shielding layer contains a coloring pigment, which may include a black pigment, in a resin binder comprising a cured product of a photosensitive resin,
Wherein the infrared transmitting layer contains a colored pigment in a resin binder comprising a cured product of a photosensitive resin,
Wherein the coloring pigments of the infrared transmitting layer are different colors from each other and include at least three kinds of colored pigments other than black. 3. The front shield according to claim 2, wherein the infrared transmitting layer is disposed between the light transmitting substrate and the shielding layer adjacent to the light transmitting substrate and the shielding layer. 4. The liquid crystal display device according to claim 3, wherein the first surface of the transparent substrate faces the front side,
And the infrared transmitting layer is disposed on the second surface of the transparent substrate. 5. The display device according to claim 4, wherein the shielding layer has one surface adjacent to the infrared transmitting layer and another surface located on the opposite side of the infrared transmitting layer,
A transparent electrode for position detection of the touch panel is formed on the other surface side of the shield layer,
Wherein the transparent electrode extends from the display area to the opaque area and is electrically connected to opaque wiring disposed in an area overlapping the shield layer with the opaque area. A display device comprising a front panel protective plate for a display device and a display panel according to any one of claims 1 to 4. The display device according to claim 6, wherein said display panel is disposed on said one surface side of said transparent substrate. The touch panel according to claim 7, further comprising a touch panel between the front panel protection plate for the display device and the display panel, wherein the touch panel includes a transparent electrode extending from an area overlapping the display area to an area overlapping the opaque area, And an opaque wiring disposed in an area overlapping the shielding layer,
Wherein the transparent electrode is electrically connected to the opaque wiring in an area overlapping the opaque area. The display device according to claim 6, wherein the display panel is a liquid crystal panel or an electroluminescence panel.

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