JP2010072581A - Color filter, display device, and method for manufacturing color filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a color filter useful for a display device having a touch panel function by an electrostatic capacity coupling system and capable of detecting a contact position of a substance contact with the display screen and capable of displaying an image. <P>SOLUTION: The color filter 50 comprises a substrate 52, a color filter layer 54 having a plurality of colored portions 56, an electrode portion 60 disposed between the color filter layer and the substrate, and a shield layer 75 disposed in the opposite side of the electrode portion to the substrate. The electrode portion is electrically connected to a circuit to detect a contact position of a substance to a display screen 12. The shield layer is insulated from the electrode portion and grounded. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a color filter used in a display device having a capacitively coupled touch panel function and capable of detecting a touch (touch) on a display surface and capable of displaying an image, a method of manufacturing the color filter, and The present invention also relates to a display device having a capacitively coupled touch panel function and capable of detecting a touch (touch) on a display surface and displaying an image.

  At present, a touch panel is widely used as an input means for various devices in which a display device having a display panel such as a liquid crystal panel is incorporated, for example, a ticket vending machine, an ATM device, a mobile phone, a game machine or the like. The touch panel is usually manufactured separately from the display panel, and is disposed on the display panel (for example, Patent Document 1).

Various methods are employed as a method of detecting the contact position of a contact object (finger, pen, etc.) on the display surface on the touch panel. As a widely used system, there is a resistive film system having two conductive films arranged so that an air layer is formed between them. In a resistive film type touch panel, a contact position on a display surface can be detected by partially conducting two conductive films by contact of a contact object.
JP 2006-23904 A

  However, when the touch panel is arranged on the display panel, light can be reflected not only on the surface closest to the viewer (in this case, the surface of the touch panel) but also on the interface between the touch panel and the display panel. As a result, more ambient light (external light) such as illumination light is reflected and the contrast is lowered, and the transmittance of image light displayed on the display panel is lowered.

  In particular, in a resistive film type touch panel, light reflection at the interface between the air layer and the conductive film becomes significant due to the refractive index difference between the air layer and the conductive film between the two conductive films. For this reason, a decrease in contrast and a decrease in the transmittance of image light become significant. In contrast, the capacitively coupled touch panel disclosed in Patent Document 1 does not require an air layer and can detect the contact position with a single conductive film. Therefore, the capacitive coupling type touch panel can display an image with superior image quality as compared with the resistive film type touch panel. However, even for a display device to which this capacitively coupled touch panel is bonded, at present, the transmittance and contrast of image light have not been evaluated to be sufficient, and further improvements are required.

  In recent years, flat panel displays having a thin display panel are widely used as display devices. However, when a separate touch panel is stacked on the display panel, there is a problem that the thickness of the entire display panel is increased.

  Further, with respect to various performances and the like for the current touch panel, for example, there is a demand for improvement in sensitivity to input, display panel thickness, manufacturing cost, and the like.

  The present invention has been made from such a viewpoint, and is used for a display device that has a capacitive touch panel function and can detect a contact position of a contact object on a display surface and display an image. Useful color filter, method for manufacturing the color filter, and useful display device capable of detecting the contact position of the contact object on the display surface and displaying an image while having a capacitively coupled touch panel function The purpose is to provide.

  A color filter according to the present invention is a color filter used in a display device having a capacitively coupled touch panel function and capable of detecting contact with a display surface, and includes a base material and a plurality of colored portions. And an electrode portion provided between the color filter layer and the base material and configured to be electrically connected to a circuit for detecting the contact when incorporated in the display device. A shield layer disposed on the side of the electrode portion opposite to the base material so as to be insulated from the electrode portion, and the shield layer has conductivity and is attached to the display device. It is configured to be grounded when assembled.

  In the color filter according to the present invention, the electrode portion includes a first electrode portion disposed between the shield layer and the base material, and a second electrode disposed between the first electrode portion and the shield layer. An insulating layer that insulates the first electrode portion and the second electrode portion is formed between the first electrode portion and the second electrode portion, and the first electrode portion Is a plurality of conductors arranged side by side in one direction, each including a plurality of conductors extending in a direction crossing the one direction, and the second electrode portion is the one direction A plurality of conductors arranged side by side in different other directions, each of which extends in a direction intersecting with the other direction, may be included. In such a color filter according to the present invention, the one direction may be orthogonal to the other direction.

  In the color filter according to the present invention, the electrode portion may be made of a planar transparent conductor, a lattice-patterned metal, or a stripe-patterned metal.

  Furthermore, in the color filter according to the present invention, the shield layer may be made of a planar transparent conductor or a lattice-patterned metal.

  Furthermore, the color filter according to the present invention further includes a transparent electrode layer disposed on a side of the color filter layer opposite to the base material, and the transparent electrode layer is provided in each pixel when incorporated in the display device. The shield layer may be disposed between the transparent electrode layer and the electrode portion so as to be insulated from the transparent electrode layer. .

  Furthermore, in the color filter according to the present invention, a positioning mark and an external portion are provided on a surface of the base on which the color filter layer is provided and in a non-display area outside the area forming the display surface. A lead-out line is formed, the external lead-out line is made of the same conductive material as the positioning mark, and is electrically connected to the electrode part, and the electrode part is connected to the contact via the external lead-out line. It may be electrically connected to a circuit for detecting. In such a color filter according to the present invention, the electrode portion may be made of the same material as the external lead-out line.

  A display device according to the present invention includes any one of the color filters described above.

  The display device according to the present invention may further include a substrate disposed to face the color filter, and a liquid crystal layer disposed between the color filter and the substrate.

  A color filter manufacturing method according to the present invention is a method for manufacturing a color filter used in a display device having a capacitively coupled touch panel function and capable of detecting contact with a display surface. A step of forming on one surface of the material and an external lead wire that is electrically connected to a circuit for detecting the contact when the color filter is incorporated in the display device. Forming on the one surface of the material, forming an electrode portion electrically connected to the external lead-out line on the side of the base on which the positioning mark is formed, and the base A step of forming a color filter layer having a plurality of colored portions on the side on which the electrode portion is formed, and the electrode portion is insulated from the electrode portion and disposed on the side opposite to the base material like Forming a shield layer that is grounded when the color filter is incorporated in the display device, and in the step of forming the color filter layer, the color filter The colored portion of the layer is formed at a position positioned with reference to the positioning mark.

  The method for producing a color filter according to the present invention is a transparent electrode layer that is insulated from the shield layer and disposed on the side of the shield layer opposite to the base material, wherein the color filter is the display device A step of forming a transparent electrode layer that functions as an electrode for controlling the display of each pixel when incorporated in the display may be further provided.

  In the color filter manufacturing method according to the present invention, the external lead line is made of the same material as the positioning mark, and the positioning mark is formed in the step of forming the positioning mark, and the external lead line is formed. The formation of the external lead line in the forming step may be performed simultaneously.

  Furthermore, in the method for manufacturing a color filter according to the present invention, the electrode part is made of the same material as the external lead-out line, and the external lead-out line is formed in the step of forming the external lead-out line, and the electrode part is formed. The formation of the electrode part in the process may be performed simultaneously.

  Furthermore, in the method for producing a color filter according to the present invention, the step of forming the electrode portion is a first electrode portion that is arranged between the shield layer and the base material, and the color filter is Forming a first electrode portion that is electrically connected to a circuit for detecting the contact when incorporated in the display device; and between the first electrode portion and the shield layer. An insulating layer to be disposed, the step of forming an insulating layer covering the first electrode portion, and the insulating layer disposed between the insulating layer and the shield layer while being insulated from the first electrode portion A second electrode portion that is electrically connected to a circuit for detecting the contact when the color filter is incorporated in the display device. And comprising the steps of: In the step of forming the electrode portion, the first electrode portion including a plurality of conductors arranged in one direction, each extending in a direction intersecting with the one direction, In the step of forming the second electrode portion formed at a position positioned with reference to a positioning mark, a plurality of conductors arranged side by side in another direction different from the one direction, each of which is A second electrode portion including a plurality of linear conductors extending in a direction crossing the other direction may be formed at a position positioned with reference to the positioning mark.

BEST MODE FOR CARRYING OUT THE INVENTION

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  In the drawings attached to the present specification, for the sake of illustration and ease of understanding, the scale, the vertical / horizontal dimension ratio, and the like are appropriately changed and exaggerated from those of the actual product.

  Further, the terms “sheet”, “film”, “plate”, and “film” used in the present case are not distinguished from each other only based on the difference in names. Thus, for example, a “sheet” is a concept that includes members and parts that may also be called films, plates, membranes, and the like.

  1 to 5 are diagrams for explaining an embodiment according to the present invention. 1 is a diagram schematically showing the configuration of the display device, FIG. 2 is a diagram showing the display panel of the display device in a cross section along the normal direction of the display surface, and FIG. 3 is a diagram of III in FIG. FIG. 4 is a cross-sectional view taken along line -III, FIG. 4 is a top view showing a color filter of the display panel, and FIG. 5 is a flowchart for explaining a method of manufacturing the color filter of the display panel.

  The display device 10 shown in FIGS. 1 to 5 has a capacitively coupled touch panel function, can detect the contact position of an external conductor (for example, a human finger) on the display surface, and displays an image. It is configured as a possible device. That is, the display device 10 functions as an output device that outputs information such as characters and drawings as an image, and also functions as an input device that inputs information by touching (touching) the display surface 12.

  Here, the term “capacitive coupling” method is used in this case as having the same meaning as that used in the technical field of touch panels. The “capacitance coupling” method is also called “capacitance” method, “capacitance coupling” method, etc. in the technical field of the touch panel. It is treated as a term that is synonymous with the method. A typical capacitively coupled touch panel includes a conductor layer. When an external conductor (typically a human finger) comes into contact with the touch panel, the external conductor and the conductor layer of the touch panel are connected. A capacitor (capacitance) is formed between them. Based on the change in the electrical state accompanying the formation of the capacitor, the position coordinates of the position where the external conductor is in contact on the touch panel are specified.

  As shown in FIGS. 1 to 5, the display device 10 according to the present embodiment has a display panel 40 configured as a liquid crystal display panel (LCD panel, liquid crystal panel). That is, in the following embodiments, an example in which the present invention is applied to a liquid crystal display device (liquid crystal display) will be described.

  As shown in FIG. 1, the display device 10 includes a display panel 40, a control unit 20 that is connected to the display panel 40 and controls driving of the display panel 40, and a display panel 40 as a liquid crystal panel on the back side (non-observer). And a surface light source device (backlight) 30 that illuminates from the side. In the present embodiment, the display panel 40 formed as a liquid crystal panel selectively transmits the planar light from the surface light source device 30 so that an image can be displayed on the display surface 12. Yes. Further, the display surface 12 of the display panel 40 functions as an input surface (touch surface, contact surface) of the touch panel. That is, information can be input to the display device 10 from the outside by bringing a conductor such as a human finger into contact with the display surface 12.

  As the surface light source device 30, for example, an edge light type or a direct type surface light source device can be used as appropriate.

  The control unit 20 includes a video information processing unit 22 that processes information regarding a video to be displayed, and an input information processing unit 24 that processes information input via the display surface 12. The video information processing unit 22 is connected to the display panel 40 and drives the display panel 40 based on the video information. That is, the video information processing unit 22 includes a circuit (drive circuit) configured to control display (transmission of light) of each pixel based on video information.

  On the other hand, the input information processing unit 24 is connected to the display panel 40 and processes information input via the display surface 12. Specifically, the input information processing unit 24 can specify the contact position of the conductor on the display surface 12 when the conductor (typically a human finger) is in contact with the display surface 12. A configured circuit (detection circuit) is included. Further, the input information processing unit 24 is connected to the video information processing unit 22 and can transmit the processed input information to the video information processing unit 22. At this time, the video information processing unit 22 can create video information based on the input information and display a video corresponding to the input information on the display surface 12.

  The video information processing unit 22 and the input information processing unit 24 of the control unit 20 are used in the video information processing unit 22 used in the conventional video display device and the conventional touch panel device, including the circuit configuration. The input information processing unit 24 can be configured in the same manner, and detailed description thereof is omitted here. As an example, Patent Document 1 (Japanese Patent Laid-Open No. 2006-23904) described above discloses an example of a circuit included in the input information processing unit 24.

  Next, the display panel 40 will be described in detail. The display panel 40 includes a configuration for enabling the display device 10 to display an image and a configuration for enabling the display device 10 to function as a touch panel. Among these, first, a configuration for functioning mainly as a video display device of the display panel 40 will be described, and then a configuration for functioning mainly as a touch panel of the display panel 40 will be described.

  As shown in FIG. 1, the display panel 40 includes a display area A1 that can display an image, and a non-display area A2 that is disposed outside the display area A1 so as to surround the display area A1. Yes. The display area A1 includes a pixel area A11 and a non-pixel area A12 that is an area outside the pixel area A11 (see FIG. 4). Here, the pixel area A11 is an area where a pixel which is a minimum element composing an image and in which image light can be transmitted is located (occupied).

  In the present embodiment, the pixel area A11 has a plurality of unit pixels (picture elements) UP that constitute one pixel, and each unit pixel UP is composed of three sub-pixels SP. The three subpixels SP selectively transmit different colors. That is, light of different wavelength bands is transmitted from the three subpixels SP. Specifically, the three sub-pixels SP are configured to selectively transmit red light, green light, and blue light, respectively, so that a color image can be displayed on the display surface 12. It has become.

  As shown in FIG. 2, a display panel 40 as a liquid crystal panel includes a first substrate 50 (hereinafter also referred to as a color filter, a color filter substrate, and a counter substrate) and a first substrate facing the first substrate 50. 50 and a liquid crystal layer 45 enclosed between the first substrate 50 and the second substrate 80, and a second substrate (hereinafter also referred to as an element substrate or an array substrate) 80 disposed on the back side (surface light source device side) 50. And have.

  As shown in FIG. 2, the first substrate 50 includes a transparent plate-like first base material 52 and a color filter layer 54. The first substrate 52 is made of, for example, a resin plate material or plate glass. The color filter layer 54 has a light shielding portion 55 that has a light shielding effect and forms the non-pixel region A12. The light-shielding portion 55 is formed with a through-opening that makes up each sub-pixel SP. The light shielding portion 55 functions as a so-called black matrix and can contribute to an improvement in contrast. In the present embodiment, a colored layer 56 (56R, 56G, 56B) colored in the display color of the subpixel SP is formed in the through-opening constituting each subpixel SP. In addition, about the detailed structure of the light-shielding part 55 and the colored layer 56, it is disclosed by various well-known literature (for example, Unexamined-Japanese-Patent No. 2005-331937), and detailed description is abbreviate | omitted here.

  Further, the first substrate 50 is appropriately provided with other components in order to effectively function as a substrate (color filter substrate) on the viewer side of the liquid crystal panel. For example, on the side of the first substrate 50 facing the liquid crystal layer 45, a transparent electrode layer 58 (see FIG. 2), an alignment film (not shown), and the like are provided, and the liquid crystal layer 45 of the first base material 52 is further provided. A polarizing plate (not shown) or the like is provided on the side opposite to the side. Among these, the transparent electrode layer 58 is configured to function as an electrode for controlling the display state of each pixel. Such a configuration is disclosed in various known documents (for example, Japanese Patent Application Laid-Open No. 2007-248816), and detailed description thereof is omitted here.

  On the other hand, as shown in FIG. 2, the second substrate 80 includes a transparent second base material 82 and pixel electrodes 84 respectively disposed in the pixel region A <b> 11 on the base material 82. In addition, a switching element 86 that controls application to the pixel electrode 84 is provided separately for each pixel electrode 84 (subpixel SP). The switching element 86 can be formed as a thin film transistor (TFT) using, for example, low-temperature polysilicon technology. The switching element 86 is electrically connected to the video information processing unit 22 of the control unit 20 described above, and operates based on a signal from a drive circuit for controlling display of each pixel of the video information processing unit 22. Various circuit wirings (not shown) such as scanning lines and signal lines (data lines) necessary for driving the switching element 86 are formed on the second substrate 84. Note that the detailed configuration, manufacturing method, operation method, and the like of the switching element 86 and circuit wiring associated with the switching element 86 are disclosed in various known documents (for example, Japanese Unexamined Patent Application Publication No. 2007-316243 and Japanese Unexamined Patent Application Publication No. 2007-248816). Here, detailed description is omitted.

  Further, the second substrate 80 is appropriately provided with other components in order to effectively function as a substrate (element substrate, array substrate) on the surface light source device side of the liquid crystal panel. For example, on the side of the second substrate 80 facing the liquid crystal layer 45, a protective layer 88 for protecting the element 86 and the like on the second base material 82, an alignment film (not shown), and the like are provided. A polarizing plate (not shown) or the like is provided on the opposite side of the second substrate 80 from the liquid crystal layer 45. Such a configuration is disclosed in various known documents (for example, Japanese Patent Application Laid-Open No. 2007-248816), and detailed description thereof is omitted here.

  The above is the configuration for the display panel 40 to function mainly as a video display device. Next, a configuration for functioning mainly as a touch panel of the display panel 40 will be described.

  As shown in FIG. 2, between the color filter layer 54 and the 1st base material 52, it has the 1st electrode part (1st electrode layer) 60 and 2nd electrode part (2nd electrode layer) which have electroconductivity. ) 70 is formed. A first insulating layer (first insulating film) 67 made of a transparent material is formed between the first electrode portion 60 and the second electrode portion 70. The first insulating layer 67 is a film-like layer and extends over the entire display area A1. As a result, the first electrode part 60 and the second electrode part 70 are insulated from each other via the first insulating layer 67.

  The first electrode unit 60 and the second electrode unit 70 are made of a conductive material (for example, ITO), and are configured to detect a contact position of the external conductor with respect to the display surface 12. It is electrically connected to 24 detection circuits. As shown in FIG. 2, the first electrode unit 60 is disposed closer to the first base material 52 (observer side) than the second electrode unit 70. In other words, the second electrode unit 70 is disposed on the color filter layer 54 side (the surface light source device 30 side) with respect to the first electrode unit 60.

  As shown in FIG. 3 showing a cross section taken along line III-III in FIG. 2, the first electrode unit 60 is a plurality of lines arranged in one direction along the plate surface of the first substrate 50. It is composed of a conductive conductor 61. The second electrode unit 70 is composed of a plurality of linear conductors 71 arranged in the other direction along the plate surface of the first substrate 50 intersecting the one direction. In the present embodiment, one direction that is the arrangement direction of the linear conductors 61 of the first electrode portion 60 and the other direction that is the arrangement direction of the linear conductors 71 of the second electrode portion 70 are orthogonal to each other. Yes.

  As shown in FIG. 3, the linear conductors 61 included in the first electrode portion 60 extend linearly in a direction intersecting with the arrangement direction (the one direction). Similarly, the linear conductors 71 included in the second electrode portion 70 extend linearly in a direction intersecting with the arrangement direction (the other direction). In particular, in the illustrated example, the linear conductors 61 included in the first electrode portion 60 extend linearly along a direction (the other direction) orthogonal to the arrangement direction (the one direction), and the second The linear conductor 71 included in the electrode unit 70 extends linearly along a direction (the one direction) orthogonal to the arrangement direction (the other direction).

  In particular, in the present embodiment, the linear conductor 61 included in the first electrode portion 60 has a line portion 61a extending linearly and a bulging portion 61b bulging from the line portion 61a. In the illustrated example, the line portion 61 a extends linearly along a direction that intersects the arrangement direction of the linear conductors 61. The bulging portion 61 b is a portion that bulges from the line portion 61 a along the plate surface of the first substrate 50. Therefore, the width of the linear conductor 61 is thicker at the portion where the bulging portion 61b is provided. As shown in FIG. 3, in the present embodiment, the linear conductor 61 has an outer contour that is substantially circular in plan view at the bulging portion 61b.

  The linear conductor 71 included in the second electrode unit 70 is configured similarly to the linear conductor 61 included in the first electrode unit 60. That is, the linear conductor 71 included in the second electrode portion 70 includes a line portion 71a extending linearly and a bulging portion 71b bulging from the line portion 71a. In the illustrated example, the line portion 71 a extends linearly along a direction intersecting with the arrangement direction of the linear conductors 71. The bulging portion 71 b is a portion that bulges from the line portion 71 a along the plate surface of the first substrate 50. Therefore, the width of the linear conductor 71 is thicker at the portion where the bulging portion 71b is provided. As shown in FIG. 3, in the present embodiment, the linear conductor 71 has an outer contour that is substantially circular in plan view at the bulging portion 71b.

  As shown in FIG. 3, when observed from the normal direction of the plate surface of the first substrate 50, each linear conductor 61 included in the first electrode portion 60 is a linear shape included in the second electrode portion 70. It intersects with the conductor 71 at many places (intersections). As shown in FIG. 3, the bulging portion 61 b of the first electrode portion 60 is disposed on the linear conductor 61 between the intersections of two adjacent linear conductors 71. Similarly, when observed from the normal direction of the plate surface of the first substrate 50, each of the linear conductors 71 included in the second electrode unit 70 has a large number of linear conductors 61 included in the first electrode unit 60. Intersects at points (intersections). Further, the bulging portion 71 b of the second electrode portion 70 is also disposed on the linear conductor 71 between the intersections of two adjacent linear conductors 61. Furthermore, in the present embodiment, the bulging portion 61b of the linear conductor 61 included in the first electrode portion 60 and the bulging portion 71b of the linear conductor 71 included in the second electrode portion 70 are It arrange | positions so that it may not overlap when it observes from the normal line direction of the plate | board surface of 1 board | substrate 50. FIG.

  Further, as shown in FIG. 3, a positioning mark (alignment mark) 65 and an external lead-out line 63 are formed on the surface of the first base member 52 on which the electrode portions 60 and 70 and the color filter layer 54 are formed. Is formed. As will be described later, the positioning mark 65 is used as a positioning reference when the electrode portions 60, 70, the color filter layer 54, and the like are formed on the first substrate 60. That is, the positions along the plate surface of the first base material 52 such as the electrode portions 60 and 70 and the color filter layer 54 are positioned with reference to the positioning mark 65.

  On the other hand, two external lead wires 63 are provided for each of the linear conductors 61 and 71 of the conductive portions 60 and 70. The external lead-out line 63 is made of a conductive material. Then, one end of the corresponding external lead wire 63 is electrically connected to both ends of each of the linear conductors 61 and 71 (see FIG. 3). Each external lead-out line 63 is electrically connected at the other end to a detection circuit of the input information processing unit 24 configured to detect a contact position of the external conductor with respect to the display surface 12. That is, the linear conductors 61 and 71 of the electrode portions 60 and 70 are electrically connected to the detection circuit that detects the contact position via the external lead-out line 63.

  The positioning mark 65 and the external lead-out line 63 are arranged in the non-display area A2 on the first base material 52. That is, the positioning mark 65 and the external lead-out line 63 are located in a region that is not observed by an observer who observes the display device 10. In the present embodiment, the external lead-out line 63 is formed of the same material as that of the positioning mark 65.

  Incidentally, as shown in FIG. 2, the display panel 40 further includes a shield layer 75 disposed on the opposite side of the second electrode unit 70 from the first base material 52. As shown in FIG. 2, the shield layer 75 is disposed between the transparent electrode layer 58 and the color filter layer 54 and the electrode portions 60 and 70. In the present embodiment, the shield layer 75 is configured as a film-like layer having conductivity and visible light transmittance, and is grounded. The shield layer 75 as a film-like layer extends and extends over the entire display area A1.

  As shown in FIG. 2, a second insulating layer (second insulating film) 77 made of a transparent material is formed between the shield layer 75 and the second electrode portion 70. The second insulating layer 77 is a film-like layer and extends over the entire display area A1. As a result, the shield layer 75 and the second electrode unit 70 are insulated from each other via the second insulating layer 77. Further, as shown in FIG. 2, a third insulating layer (third insulating film) 79 made of a transparent material is formed between the color filter layer 54 and the transparent electrode layer 58. The third insulating layer 79 is a film-like layer and extends over the entire display area A1. As a result, the shield layer 75, the color filter layer 54, and the transparent electrode layer 58 are insulated from each other through the third insulating layer 79.

  Next, an example of a method for manufacturing the first substrate having the above configuration will be described mainly with reference to FIG.

  As shown in FIG. 5, first, as the first step S1, a transparent base material that forms the first base material 52 is prepared. Although a plate glass is typically used as the transparent substrate, the present invention is not limited to this, and a resin plate may be used as a transparent substrate for constituting the first substrate 52.

  Next, as the second step S <b> 2, the positioning mark 65 and the external lead-out line 63 described above are formed on one surface of the first base material 52. At this time, the positioning mark 65 and the external lead-out line 63 can be simultaneously formed from the same material by the same etching process using a photolithography technique. As a material forming the positioning mark 65 and the external lead-out line 63, for example, a material having high conductivity such as copper or aluminum and available at a relatively low cost can be used.

  According to such a method, the positioning mark 65 and the external lead-out line 63 can be efficiently formed on the first base material 52. Further, since the positioning mark 65 and the external lead line 63 are formed by the same etching process using a photolithography technique, the external lead line 63 is accurately formed at a fixed position with respect to the positioning mark 65. It becomes like this. In other words, the external lead-out line 63 is positioned very easily and accurately with respect to the positioning mark 65 on the plane along the plate surface of the first substrate 50.

  Thereafter, as the third step S3, the above-described first electrode portion 60 is formed on the side of the first base material 52 on which the positioning mark 65 is formed. The first electrode unit 60 can be formed by sputtering, vapor deposition, etching using a photolithography technique, or the like. As a material forming each linear conductor 61 of the first electrode part 60, for example, a conductive material such as ITO (indium tin oxide) can be used. When forming the first electrode portion 60, each linear conductor 61 of the first electrode portion 60 can be formed by positioning with reference to the positioning mark 65 already formed on the first base member 52. it can. According to such a method, the first electrode unit 60 can be positioned very easily and accurately with respect to the positioning mark 65 in a plane along the plate surface of the first substrate 50. Thereby, both ends of each linear conductor 61 of the first electrode portion 60 can be reliably brought into contact with the external lead wire 63 already formed on the first base material 52.

  Next, as the fourth step S <b> 4, the first insulating layer 67 described above is formed so as to cover the first electrode unit 60. Specifically, the first insulating layer 67 may be formed by laminating a commercially available transparent insulating film on the first base material 50 so as to cover the first electrode portion 60, or The first insulating layer 67 may be formed by coating the first base material 50 with a coating liquid that forms the first insulating layer 67 so as to cover the first electrode portion 60. In addition, as a material which makes the 1st insulating layer 67, various transparent insulating materials, such as UV curable acrylic resin, can be used, for example.

  Thereafter, as the fifth step S5, the above-described second electrode portion 70 is formed. The second electrode unit 70 can be formed on the first insulating film 66 in the same manner as the first electrode unit 60 described above. That is, when forming the second electrode portion 70, each linear conductor 71 of the second electrode portion 70 can be formed by positioning with reference to the positioning marks 65 already formed on the first base material 52. it can. According to such a method, the second electrode portion 70 can be positioned very easily and accurately with respect to the positioning mark 65 in a plane along the plate surface of the first substrate 50. Thereby, both ends of each linear conductor 71 of the second electrode part 70 can be brought into contact with the external lead-out line 63 already formed on the first base material 52 with certainty. In addition, about the formation method of the 2nd electrode part 70, the other description which overlaps with the formation method of the 1st electrode part 60 is abbreviate | omitted.

  Next, as the sixth step S6, the above-described second insulating layer 77 is formed. The second insulating layer 77 can be formed so as to cover the second electrode portion 70 in the same manner as the first insulating layer 67 described above. Therefore, the overlapping description is omitted here.

  Thereafter, the shield layer 75 described above is formed on the second insulating layer 77 as a seventh step S7. As an example, the shield layer 75 can be formed by depositing a material that forms the shield layer 75 on the second insulating layer 77 by sputtering. In addition, as a material which makes the shield layer 75, the material which has various translucency and electroconductivity, such as ITO (indium tin oxide), can be used, for example. The shield layer 75 is grounded via a terminal formed on the base material 52, for example.

  Next, as an eighth step S <b> 8, the color filter layer 54 is formed on the shield layer 75. As a specific example, first, the matrix-shaped light shielding portion 55 can be formed on the shield layer 75 by etching using a photolithography technique. When forming the light shielding part 55, the light shielding part 55 can be formed by positioning with reference to the positioning marks 65 already formed on the first base material 52. According to such a method, the light shielding portion 55 can be positioned very easily and accurately with respect to the positioning mark 65 in a plane along the plate surface of the first substrate 50.

  Next, the colored portions 56R, 56G, and 56B can be formed by patterning using a photolithography technique or by inkjet printing. When forming the colored portions 56R, 56G, and 56B, the colored portions 56R, 56G, and 56B can be formed by positioning using the positioning marks 65 already formed on the first base member 52 as a reference. According to such a method, the colored portions 56R, 56G, and 56B can be positioned very easily and accurately with respect to the positioning mark 65 on the plane along the plate surface of the first substrate 50. That is, the colored portions 56R, 56G, and 56B can be positioned very easily and accurately with respect to the light shielding portion 55 that is positioned with the positioning mark 65 as a reference.

  Furthermore, the color filter layer 54 formed in this way is also accurately positioned with respect to the first electrode portion 60 and the second electrode portion 70 that are positioned with reference to the positioning mark 65. In other words, each linear conductor 61 of the first electrode portion 60 and each linear conductor 71 of the second electrode portion 70 are positioned extremely accurately with respect to the pixel array defined by the color filter layer 54. For this reason, as will be described later, the position coordinates of the contact position of the external conductor with respect to the display surface 12 can be specified extremely accurately in correspondence with the pixel arrangement. That is, the display device substrate 50 having an excellent resolution touch panel function can be provided at a low cost by an extremely easy manufacturing method.

  Next, as the ninth step S <b> 9, the above-described third insulating layer 79 is formed on the color filter layer 54. The third insulating layer 79 can be formed on the color filter layer 54 in the same manner as the first insulating layer 67 and the second insulating layer 77 described above. Therefore, the overlapping description is omitted here.

  Thereafter, as the tenth step S <b> 10, the above-described transparent electrode layer 58 is formed on the third insulating layer 79. As an example, the transparent electrode layer 58 can be formed by depositing a material that forms the transparent electrode layer 58 on the third insulating layer 79 by sputtering. In addition, as a material which makes the transparent electrode layer 58, the material which has various translucency and electroconductivity, such as ITO (indium tin oxide), can be used, for example.

  Finally, a first substrate 50 is manufactured by forming a polarizing plate, an alignment film, and the like that are not shown in FIG.

  According to the manufacturing method as described above, the external lead-out line 63, the first electrode part 60, the second electrode part 70, and the color filter layer are based on the positioning mark 65 formed first on the first base material 52. The light shielding portion 55 and the coloring portion 56 of the color filter layer 54 are positioned. Therefore, the external lead-out line 63 and the linear conductor 61 of the first electrode unit 60 can be reliably electrically connected. Similarly, the external lead wire 63 and the linear conductor 71 of the second electrode portion 70 can be reliably electrically connected. In addition, the colored portions 56R, 56G, and 56B of the respective colors can be reliably formed in the through openings of the light shielding portion 54 of the color filter layer 54. Thereby, the color filter layer 54 free from color mixing or color loss can be obtained. Further, since the linear conductors 61 and 71 and the color filter layer 54 are positioned with reference to the same positioning mark 65, the position coordinates of the linear conductors 61 and 71 with respect to the pixel array can be accurately specified. Will be able to. As a result, the display device 10 having a touch panel function that can accurately detect the contact position of the external conductor to the display surface 12 can be easily and inexpensively manufactured.

  Next, an effect | action at the time of using the above display apparatuses 10 is demonstrated. As described above, the display device 10 according to the present embodiment is configured to function as a device for displaying video and also as a touch panel. Among these, first, the operation of the display device 10 when functioning as a device for displaying video will be described, and then the operation of the display device 10 when functioning as a touch panel will be described.

  When the display device 10 is used as a device for displaying an image, the switching element 86 provided on the element substrate 80 is operated by the control from the image information processing unit 22 of the control unit 20. Thereby, transmission of light from each pixel is controlled, and a desired image is displayed on the display surface 12.

  As described above, the display device 10 also functions as a capacitively coupled touch panel. In the present embodiment, the electrode units 60 and 70 included in the capacitively coupled touch panel are not supported by an independent support base material, but are supported by the color filter substrate 50 of the display device 10. Therefore, the number of interfaces that can reflect ambient light (external light) such as illumination, image light, and the like can be reduced compared to pasting a touch panel separate from the display device to the display surface of the display device. it can. Thereby, the transmittance | permeability of image light rises and energy efficiency improves, and the contrast of the image | video displayed on the display apparatus 10 can be improved by suppressing reflection of environmental light. From the above, according to the display device 10 according to the present embodiment, it is possible to display an image with excellent image quality although a touch panel function is provided.

  Next, the operation when used as a touch panel will be described.

  When an external conductor (for example, a human finger) contacts the display surface 12, the linear conductors 61, 70 of the electrode portions 60, 70 located in the vicinity of the contact position of the external conductor with the display surface 12 by the external conductor, 71 function as an electrode, and electrolysis is formed. At this time, the first base member 52 and the like positioned between the outer conductor and the linear conductors 61 and 71 function as a dielectric. That is, when the outer conductor comes into contact with the display surface 12, a capacitor having the outer conductor and the electrode portions 60 and 70 as electrodes is formed.

  The detection circuit of the input information processing unit 24 of the control unit 20 is connected to the linear conductors 61 and 71 so that the capacitance between the linear conductors 61 and 71 and the external conductor can be detected. It has become. Then, the input information processing unit 24 detects a change in capacitance between each of the linear conductors 61 and 71 and the outer conductor, so that the outer conductor becomes any of the linear conductors 61 of the first electrode unit 60. As well as which linear conductor 71 of the second electrode portion 70 the outer conductor faces.

  That is, the detection circuit of the input information processing unit 24 specifies a linear conductor facing the external conductor from the linear conductors 61 of the first electrode unit 60 arranged side by side in the one direction. The position of the outer conductor on the coordinate axis extending in the one direction is specified. Similarly, the detection circuit of the input information processing unit 24 specifies the linear conductor facing the external conductor from the linear conductors 71 of the second electrode unit 70 arranged in the other direction. Thus, the position of the outer conductor on the coordinate axis extending in the other direction is specified. In this way, the position coordinates of the contact position of the external conductor on the display surface 12 can be accurately identified on the display surface 12 by detecting the contact position of the external conductor on the display surface 12 in two directions. Can do.

  Further details of the method for detecting the contact position on the capacitively coupled touch panel are disclosed in, for example, the above-mentioned Patent Document 1 (Japanese Patent Laid-Open No. 2006-23904), and further description thereof is omitted here. To do.

  As shown in FIG. 2, the first electrode portion 60 and the second electrode portion 70 are arranged at different positions along the normal direction to the plate surface of the substrate 50. Specifically, the second electrode unit 70 is disposed at a position farther from the display surface 12 than the first electrode unit 60. In other words, the second electrode unit 70 is disposed at a position farther from the display surface 12 than the first electrode unit 60. For this reason, depending on the position on the display surface 12 with which the outer conductor contacts, the linear conductor 61 of the first electrode portion 60 is interposed between the outer conductor and the linear conductor 71 of the second electrode portion 70. Will come to do. In this case, the capacitor may not be effectively formed between the outer conductor and the second electrode portion 70.

  On the other hand, according to the present embodiment, as shown in FIG. 3, the linear conductor 61 of the first electrode portion 60 has the line portion 61 a and the bulging portion 61 b, and the linear shape of the second electrode portion 70. The conductor 71 has a line portion 71a and a bulging portion 71b. In each of the linear conductors 61 and 71, the width of the bulging portions 61b and 71b is very thick compared to the width of the line portions 61a and 71a. As described above, the bulging portion 61b of the linear conductor 61 included in the first electrode portion 60 and the bulging portion 71b of the linear conductor 71 included in the second electrode portion 70 are the first It arrange | positions so that it may not overlap, when it observes from the normal line direction of the board surface of the board | substrate 50. FIG.

  Therefore, when the outer conductor comes into contact with the display surface 12, a capacitor can be stably formed between the outer conductor and the linear conductor 71 of the second electrode portion 70. As a result, the contact position (touch position) of the outer conductor with the contact surface 12 can be detected with high sensitivity and accuracy in a direction parallel to the arrangement direction of the linear conductors 71 of the second electrode unit 70. Become. In addition, while realizing highly sensitive touch position detection, it is possible to effectively use ITO to reduce the amount of expensive ITO used and to reduce costs.

  By the way, when the display device 10 displays an image, a voltage is applied between the pixel electrode 84 and the transparent electrode layer 58 by driving the switching element 86 in order to control display in each pixel. And when this inventor repeated earnest research, due to the application of this voltage, an electrical noise may be added to the detection circuit for detecting the contact of the external conductor to the display surface 12. It was discovered. On the other hand, according to the present embodiment, the grounded shield layer 75 is provided between the transparent electrode layer 58 and the electrode portions 60 and 70. The shield layer 75 can prevent electrical interference between a drive circuit that functions as a video display device and a detection circuit that functions as a touch panel. Thereby, the contact of the external conductor to the display surface 12 can be accurately detected with high sensitivity.

  Further, as described above, the video information processing unit 22 and the input information processing unit 24 of the control unit 20 are connected. The input information processing unit 24 can transmit information input when the conductor contacts a predetermined position on the display surface 12 to the video information processing unit 22. Based on the input information read by the input information processing unit 24, the video information processing unit 22 can display a video corresponding to the input information on the display device 10. That is, information is exchanged in an interactive manner between the user (operator) of the display device 10 and the display device 10 by the display function as the output means and the touch panel function as the input means (for example, the user's An instruction to the display device 10 and execution of the instruction by the display device 10) can be realized.

  In particular, as described above, when the linear conductors 61 and 71 and the color filter layer 54 are positioned with reference to the same positioning mark 65, the linear conductors 61 and 71 and the color filter phase 54 are arranged. The pixel arrays defined by can be accurately positioned relative to each other. In this case, the contact position of the external conductor on the display surface 12 can be detected with high accuracy corresponding to the pixel arrangement. As a result, the input corresponding to the video information displayed on the display surface 12 can be detected with high resolution and high accuracy, and thereby, between the user (operator) of the display device 10 and the display device 10. The exchange of information in the form of dialogues will proceed very smoothly.

  According to the present embodiment as described above, the substrate 50 for a display device includes a plate-like base material 52, a color filter layer 54 having a plurality of colored portions 56, a color filter layer 54, and a base material 52. And electrode portions 60 and 70 configured to be electrically connected to a circuit for detecting contact when incorporated in the display device 10. That is, the electrode portions 60 and 70 for the capacitive coupling touch panel are formed on the substrate 50 for the display device, and the touch panel function is given to the display panel 12 of the display device 10. Thereby, compared with bonding a separate touch panel to the display surface of a display apparatus, manufacturing cost can be reduced significantly. In addition, the number of interfaces that can reflect ambient light (external light) such as illumination, image light, and the like can be reduced as compared with bonding a separate touch panel to the display surface of the display device. Thereby, the transmittance | permeability of image light rises and energy efficiency improves, and the contrast of the image | video displayed on the display apparatus 10 can be improved by suppressing reflection of environmental light. Furthermore, the total thickness of the display panel portion of the display device can be greatly reduced as compared to bonding a separate touch panel to the display surface of the display device.

  Further, since the electrode portions 60 and 70 and the color filter layer 54 are disposed on the same side of the plate-like base material 52, the electrode portions 60 and 70 and the color filter layer 54 are sequentially formed on the base material 52. Accordingly, the display device substrate 10 in which the electrode portions 60 and 70 for the capacitively coupled touch panel are incorporated can be easily and inexpensively manufactured.

  Further, as a touch panel function, a capacitive coupling system is adopted instead of the most widely used resistive film system. In the resistance film system, it is necessary to dispose two conductive films apart via an air layer. On the other hand, in the capacitive coupling method, since it is not necessary to separate the two conductive films by the air layer, reflection at the interface between the air layer and the conductive film, particularly total reflection caused by a difference in refractive index, Problems such as the occurrence of Newton rings due to the interposition of layers can be avoided. In the first place, in the capacitive coupling method, it is not necessary to provide two conductive films, which can not only improve the image quality but also make the display device 10 thinner and less expensive.

  Further, according to the present embodiment, the first electrode portion 60 and the second electrode portion 70 including the linear conductors 61 and 71 extending in different directions along the display surface 12 are provided. The contact position of the outer conductor (typically, a human finger) with respect to the display surface 12 is the position in the arrangement direction of the linear conductors 61 included in the first electrode unit 60 and the second electrode unit 70. It is configured to be identified by being decomposed into a position in the arrangement direction of the included linear conductors 71. According to such a method, the position coordinates of the contact position of the external conductor on the display surface 12 can be detected with extremely high accuracy.

  Note that various modifications can be made to the above-described embodiment. Hereinafter, an example of modification will be described.

  For example, in the above-described embodiment, the example in which the first electrode unit 60 and the second electrode unit 70 are formed from ITO has been described, but the present invention is not limited thereto. For example, the electrode parts 60 and 70 may be made of the same material as the external lead-out line 63. As an example, the electrode portions 60 and 70 may be formed in a stripe shape using the same metal (copper, aluminum, or the like) as the external lead-out line 63. When the electrode portions 60 and 70 are not formed as a film (sheet) extending in the display area A1, the electrode portions 60 and 70 are made of a material that does not have translucency (for example, a metal such as copper or aluminum). The electrode portions 60 and 70 can be designed so that the image light transmitted through the electrode portions 60 and 70 can be observed to a desired degree. That is, the electrode portions 60 and 70 are not limited to a planar (sheet-like) transparent conductor, but may be a metal layer patterned in a lattice shape (mesh shape) or a metal layer patterned in a stripe shape (stripe shape). Can also be configured.

  In the above-described embodiment, the example in which the electrode portions 60 and 70 are manufactured in a separate process from the external lead-out line 63 is shown, but the present invention is not limited to this. For example, when the electrode part 60 is made of the same material as the external lead-out line 63, the electrode part 60 may be formed at the same time when the external lead-out line 63 is formed. For example, the striped pattern (stripe pattern) electrode portion may be made of metal integrally with the external extraction line 63 by etching using a photolithography technique.

  Furthermore, in the above-described embodiment, the linear conductor 61 of the first electrode portion 60 has the line portion 61a and the bulging portion 61b, and the linear conductor 71 of the second electrode portion 70 has the line portion 71a. The example which has the bulging part 71b was shown. Further, in the above-described embodiment, the example in which the bulging portions 61b and 71b are formed in a substantially circular shape in plan view is shown. However, the present invention is not limited thereto, and as an example, the bulging portions 61b and 71b may have a square shape such as a square or a rhombus in plan view. Moreover, the linear conductors 61 and 71 may not have the bulging portions 61b and 71b but may have a linear outline.

  Further, in the above-described embodiment, the example in which the linear conductor 61 of the first electrode unit 60 and the linear conductor 71 of the second electrode unit 70 are configured in the same manner has been described. I can't. For example, as illustrated in FIG. 6, the line width w <b> 2 of the conductor 71 of the second electrode unit 70 is closer to the display surface 12 (observer side surface) of the display device 10. The conductor 61 may be thicker than the line width w1. According to such an example, when the external conductor comes into contact with the display surface 12, the linear shape of the second electrode unit 70 disposed at a position relatively far from the display surface 12 (observer side surface) of the display device 10. A capacitor can be formed stably between the conductor 71 and the external conductor. In addition, the outer conductor and the second electrode portion in contact with the display surface 12 are compared with the capacitance of the capacitor formed between the outer conductor in contact with the display surface 12 and the conductor 61 of the first electrode portion 60. It is possible to prevent the capacitance of the capacitor formed between the 70 conductors 71 from becoming low. As a result, the contact position (touch position) of the outer conductor with respect to the contact surface 12 is not limited to the direction parallel to the arrangement direction of the linear conductors 61 of the first electrode unit 60 but also the linear conductivity of the second electrode unit 70. Even in a direction parallel to the arrangement direction of the bodies 71, it becomes possible to detect with extremely high sensitivity and accuracy.

  In addition, in the modification shown in FIG. 6, about the structure of another part, it can comprise similarly to embodiment mentioned above. In FIG. 6, parts that can be configured in the same manner as the above-described embodiment are given the same reference numerals, and redundant descriptions are omitted.

  Furthermore, in the above-described embodiment, the example in which the two electrode portions of the first electrode portion 60 and the second electrode portion 70 are provided has been described, but the present invention is not limited thereto. As an example, the second electrode unit 70 may be omitted. In other words, only one electrode portion may be provided. In this case, an electrode part can be comprised from a film-form transparent conductor, the conductor of a lattice pattern (mesh pattern), etc. For example, by applying voltage from the four corners of the electrode portion and observing the current value of the current flowing from the four corners when the outer conductor is in contact with the display surface (at the time of touch), the contact position of the outer conductor on the display surface 12 Can be specified on a coordinate axis along the display surface.

  Further, in the above-described embodiment, the positioning mark 65 and the external lead-out line 63 are simultaneously formed from the same material by the same etching process using a photolithography technique, but the present invention is not limited to this. The positioning mark 65 may be formed first, and the external lead-out line 63 may be formed using the formed positioning mark 65 as a reference. Further, at this time, the electrode part 60 may be formed integrally with the external lead-out line 63 from the same material as the external lead-out line 63. Also by such a method, the external lead-out line 63 can be accurately positioned with respect to the positioning mark 65 that has been formed on a plane along the plate surface of the first substrate 50.

  Furthermore, in the above-described embodiment, the example in which the shield layer 75 is formed as a film-like transparent electrode layer made of ITO is shown, but the present invention is not limited to this. For example, when the shield layer 75 is not formed as a film (sheet) extending in the display area A1, the shield layer 75 is formed from a material that does not transmit light (for example, a metal such as copper or aluminum). In addition, the shield layer 75 can be designed so that the image light transmitted through the shield layer 75 can be observed to a desired degree. That is, the shield layer 75 is not limited to a sheet-like transparent conductor, and may be configured from a metal layer or the like patterned in a lattice shape (mesh shape).

  Furthermore, in the above-described embodiment, the example in which the insulating layer 79 is provided between the color filter layer 54 and the transparent electrode layer 58 has been described, but the present invention is not limited thereto. An insulating layer 79 may be provided between the color filter layer 54 and the shield layer 75. When the shield layer 75 is insulated from the transparent electrode layer 58, the insulating layer 79 can be omitted.

  Furthermore, although the example which comprises a liquid crystal display device (liquid crystal display panel) using the 1st board | substrate (counter substrate, display apparatus substrate) 50 was shown in embodiment mentioned above, it is not restricted to this. By using the first substrate 50 described above, a display device other than the liquid crystal display device, for example, an EL display device or a plasma display can be configured. Further, when it is not necessary to arrange an electrode (transparent electrode layer 58) for controlling the display of each pixel on the first substrate (counter substrate, display device substrate) 50, naturally, the first substrate. The transparent electrode layer 58 may be deleted from the (opposite substrate, display device substrate) 50.

  In addition, although the some modification with respect to embodiment mentioned above was demonstrated above, naturally, it is also possible to apply combining several modifications suitably.

FIG. 1 is a diagram for explaining an embodiment according to the present invention and schematically showing a configuration of a display device. FIG. 2 is a cross-sectional view showing the display panel incorporated in the display device of FIG. 1 in a cross section along the normal direction to the display surface of the display device. FIG. 3 is a view for explaining the configuration of the electrode portion of the display device substrate (first substrate) incorporated in the display panel of FIG. 2, and shows the display panel with the color filter layer and the like removed. It is a top view. Note that FIG. 3 substantially corresponds to a cross-sectional view taken along the line III-III in FIG. FIG. 4 is a plan view showing a color filter layer of a display device substrate (first substrate) incorporated in the display panel of FIG. FIG. 5 is a flowchart for explaining an example of a method of manufacturing a display device substrate (first substrate) incorporated in the display panel of FIG. FIG. 6 is a diagram corresponding to FIG. 3 and is a diagram for explaining a modification of the electrode portion.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Display apparatus 12 Display surface 20 Control part 30 Surface light source device 40 Display panel 45 Liquid crystal layer 50 Color filter (opposite board | substrate, 1st board | substrate, display apparatus board | substrate, color filter board | substrate)
52 Base material (first base material)
54 Color filter layers 56, 56R, 56G, 56B Colored portion 58 Transparent electrode layer 60 First electrode portion (electrode portion)
61 Conductor (Linear conductor)
63 External lead-out line 65 Positioning mark (alignment mark)
67 Insulating layer (insulating film)
70 Second electrode part (electrode part)
71 Conductor (Linear Conductor)
75 Shield layer 77 Insulating layer (insulating film)
79 Insulating layer (insulating film)
80 substrate (second substrate, element substrate, array substrate)

Claims (15)

A color filter used in a display device having a touch panel function of a capacitive coupling method and capable of detecting contact with a display surface,
A substrate;
A color filter layer having a plurality of colored portions;
An electrode unit provided between the color filter layer and the base material and configured to be electrically connected to a circuit for detecting the contact when incorporated in the display device;
A conductive shield layer disposed on the side of the electrode portion opposite to the base material so as to be insulated from the electrode portion;
The color filter, wherein the shield layer is configured to be grounded when incorporated in the display device. The electrode portion includes a first electrode portion disposed between the shield layer and the base material, and a second electrode portion disposed between the first electrode portion and the shield layer. ,
An insulating layer that insulates the first electrode portion and the second electrode portion is formed between the first electrode portion and the second electrode portion,
The first electrode unit includes a plurality of conductors arranged in one direction, each including a plurality of conductors extending in a direction intersecting the one direction,
The second electrode portion includes a plurality of conductors arranged side by side in another direction different from the one direction, each including a plurality of conductors extending in a direction intersecting the other direction. The color filter according to claim 1, wherein The color filter according to claim 2, wherein the one direction is orthogonal to the other direction. The color filter according to any one of claims 1 to 3, wherein the electrode portion is made of a planar transparent conductor, a grid-like metal, or a striped metal. The color filter according to claim 1, wherein the shield layer is made of a planar transparent conductor or a grid-like metal. A transparent electrode layer disposed on the side of the color filter layer opposite to the substrate, further comprising:
The transparent electrode layer is configured to function as an electrode for controlling display of each pixel when incorporated in the display device,
The said shield layer is arrange | positioned between the said transparent electrode layer and the said electrode part so that it may be insulated from the said transparent electrode layer, The Claim 1 characterized by the above-mentioned. Color filter. On the surface of the substrate on which the color filter layer is provided, a positioning mark and an external lead-out line are formed in a non-display area outside the area forming the display surface,
The external lead wire is made of the same conductive material as the positioning mark, and is electrically connected to the electrode portion,
The collar according to claim 1, wherein the electrode unit is electrically connected to a circuit for detecting the contact via the external lead-out line. filter. The color filter according to claim 7, wherein the electrode portion is made of the same material as the external lead-out line. A display device comprising the color filter according to claim 1. A substrate disposed opposite to the color filter;
The display device according to claim 9, further comprising: a liquid crystal layer disposed between the color filter and the substrate. A method of manufacturing a color filter used in a display device having a capacitive touch panel touch panel function and capable of detecting contact with a display surface,
Forming a positioning mark on one surface of the substrate;
Forming an external lead line on the one surface of the base material, which is electrically connected to a circuit for detecting the contact when the color filter is incorporated in the display device; ,
Forming an electrode part electrically connected to the external lead-out line on the side where the positioning mark of the base material is formed;
A shield layer that is insulated from the electrode portion and disposed on the side of the electrode portion opposite to the base material, and is grounded when the color filter is incorporated in the display device. Forming a shield layer,
Forming a color filter layer having a plurality of colored portions on the side of the substrate on which the electrode portion is formed, and
In the step of forming the color filter layer, the colored portion of the color filter layer is formed at a position positioned with reference to the positioning mark. A transparent electrode layer that is insulated from the shield layer and disposed on the side of the shield layer opposite to the substrate, and displays each pixel when the color filter is incorporated in the display device The method for producing a color filter according to claim 11, further comprising a step of forming a transparent electrode layer that functions as an electrode for controlling the temperature. The external lead line is made of the same material as the positioning mark,
The formation of the positioning mark in the step of forming the positioning mark and the formation of the external lead-out line in the step of forming the external lead-out line are performed simultaneously. Manufacturing method of color filter. The electrode portion is made of the same material as the external lead wire,
The formation of the external lead-out line in the step of forming the external lead-out line and the formation of the electrode part in the step of forming the electrode part are performed at the same time. The manufacturing method of the color filter of description. The step of forming the electrode part includes
A first electrode unit arranged between the shield layer and the base material, and electrically connected to a circuit for detecting the contact when the color filter is incorporated in the display device Forming a first electrode portion to be connected;
Forming an insulating layer to be disposed between the first electrode portion and the shield layer, the insulating layer covering the first electrode portion;
A second electrode unit disposed between the insulating layer and the shield layer in a state of being insulated from the first electrode unit, wherein the color filter is incorporated into the display device; Forming a second electrode portion to be electrically connected to a circuit for detecting contact,
In the step of forming the first electrode portion, the first electrode portion includes a plurality of conductors arranged side by side in one direction, each extending in a direction intersecting the one direction. Is formed at a position positioned with reference to the positioning mark,
In the step of forming the second electrode portion, a plurality of conductors arranged side by side in another direction different from the one direction, each extending in a direction intersecting the other direction The method for producing a color filter according to claim 11, wherein the second electrode portion including the conductor is formed at a position positioned with reference to the positioning mark. .

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