JP2015148743A - information display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid reduction in visibility due to the wirings for applying voltage to electrodes even when the electrodes are highly integrated.SOLUTION: The formation height on a base material 14 of wirings 12a to 12g for applying voltage to display electrodes 11a to 11g is lower, by 3 μm or more, than the formation height on the base material 14 of a background electrode 13 formed along both sides of the wirings 12a to 12g; and the background electrode 13 extends along the wirings 12a to 12g, has width in a direction orthogonal to the direction where the wirings extend of 100 μm or more, and is provided at distance from the wirings of 410 μm or less while not in contact with the wirings.

Description

  The present invention relates to an information display device that displays information based on a voltage applied to an electrode layer in an information display layer sandwiched between two opposing electrode layers.

  Conventionally, as a display device for displaying information, a CRT display, a liquid crystal display, a plasma display, and the like are used. These are used in a television receiver to display a television image transmitted from a television station or a personal computer. It is possible to display information stored in a personal computer or information distributed via the Internet.

  In recent years, in addition to the display devices described above, thin information display devices that display digital information on a thin display medium such as paper have begun to spread. As such a thin information display device, for example, when an information display layer in which a chargeable particle is dispersed in a liquid is sandwiched between two opposing electrode layers, a voltage is applied to the two electrode layers. There is an electrophoretic display in which information is displayed by moving charged particles in a liquid. Such a thin information display device is easy to carry because it is thin like paper, consumes less power, has a wide viewing angle, and rewrites information displayed by the voltage applied to the electrodes. In addition, the display contents can be retained even when the power is turned off.

  7A and 7B are diagrams showing a laminated structure of a general electrophoretic display, in which FIG. 7A is a diagram showing the entire laminated structure, and FIG. 7B is an enlarged view of a portion A shown in FIG.

  As shown in FIG. 7A, a general electrophoretic display has a transparent electrode (for example, ITO: Indium Tin Oxide) 121 formed on one surface of a transparent substrate 122 made of glass, transparent film, or the like. The information display layer 130 is sandwiched between the conductive film substrate 120 and the insulating layer 117 stacked on the base substrate 114.

  A plurality of display electrodes 111 and a background electrode 113 for displaying information using the information display layer 130 are formed on the surface of the insulating layer 117 facing the information display layer 130, and information on the insulating layer 117 is displayed. A wiring 112 for applying a voltage to the display electrode 111 is formed on the surface opposite to the display layer 130, and the plurality of display electrodes 111 are connected to each other through a conduction portion 116 formed in the insulating layer 117. It is connected to the wiring 112. Also in the background electrode 113, wiring (not shown) for applying a voltage to the background electrode 113 is formed on the base substrate 114, and is connected to this wiring.

  As shown in FIG. 7B, the information display layer 130 is configured such that the partition wall liquid 132 in which the chargeable particles 133 are dispersed is accommodated in a region surrounded by the partition wall 131 and the seal layer 134. The partition wall 131 includes a bottom portion, a side portion serving as an outer peripheral portion of the information display layer 130, and a wall portion for partitioning a region surrounded by the side portion into a plurality of regions, and a surface opposite to the bottom portion is formed. It has an open shape. And it laminates | stacks so that the bottom part side may oppose the base base material 114, and the sealing layer 134 is laminated | stacked on the opened side.

  In the electrophoretic display configured as described above, when a predetermined voltage is applied to the background electrode 113 and a voltage is selectively applied to the display electrode 111 while the transparent electrode 121 is at a reference potential. In the partition wall liquid 132, the chargeable particles 133 move by Coulomb force, and in a region facing the background electrode 113, the background electrode 113 and the transparent electrode 121 are arranged on a predetermined side, and on the display electrode 111. In the opposing region, the display electrode 111 and the transparent electrode 121 are attracted to either one of the display electrode 111 and the transparent electrode 121 in accordance with the voltage applied to the display electrode 111. The partition wall liquid 132 is colored with a dye or pigment, and the chargeable particles 133 include a light scattering component having a high refractive index, so that the display electrode 111 side is charged when viewed from the transparent conductive film substrate 120 side. The region where the conductive particles 133 are attracted appears to be colored, and the region where the charged particles 133 are attracted toward the transparent electrode 121 side appears white. Thereby, one of the first and second voltages is applied to the desired display electrode 111 of the display electrodes 111, and the other of the first and second voltages is applied to the other display electrodes 111 and the background electrode 113. As a result, only the region facing the desired display electrode 111 looks different in color from the other regions, and desired information is expressed by this color difference.

  Here, in the electrophoretic display as described above, it is necessary to form the conductive portion 116 in the insulating layer 117 in order to connect the display electrode 111 and the wiring 112, but for applying a voltage to the display electrode 111. By arranging the wiring 112 between the plurality of display electrodes 111, it is not necessary to form the conductive portion 116 in the insulating layer 117, and a process for that is not necessary, and further, the insulating layer 117 itself is not necessary, thereby reducing the cost. Can be planned.

  However, in the case where the wiring 112 is arranged between the plurality of display electrodes 111, when a voltage is selectively applied to the display electrode 111 via the wiring 112, the above-described region is also displayed in the region facing the wiring 112 of the information display unit 130. As described above, the charged particles 133 move by the Coulomb force in the partition wall liquid 132, and when viewed from the transparent conductive film substrate 120 side, the region where the charged particles 133 are attracted to the wiring 112 side is colored. In addition, the region where the chargeable particles 133 are attracted to the transparent electrode 121 side appears white, so that the visibility of information displayed by the display electrode 111 is lowered.

  Therefore, the formation height of the wiring 112 on the base substrate 114 is made lower than the formation height of the display electrode 111 adjacent to the wiring 112 on the base substrate 114, thereby facing the wiring 112 of the information display layer 130. In such a region, the distance between the wiring 112 and the information display layer 130 is widened to make it less susceptible to the voltage applied to the wiring 112, thereby reducing the visibility of information displayed by the display electrode 111. A technique for avoiding this is considered (for example, see Patent Document 1).

  In addition, in a configuration in which the display electrodes are formed in an island-like state on the base substrate, the formation height of the wiring for applying a voltage to the isolated display electrode on the base substrate is defined as the display electrode formation height. In the same manner as described above, a region facing the wiring of the information report display layer is formed by forming a bank member along the both sides of the wiring. In this technology, the distance between the wiring and the information display layer is widened to make it less susceptible to the voltage applied to the wiring, thereby avoiding a decrease in the visibility of information displayed by the display electrode. (For example, refer to Patent Document 2).

  In these techniques, even in the configuration having the background electrode as described above, when the wiring is formed between the background electrodes, the formation height of the wiring on the base substrate is made lower than the formation height of the background electrode. Thus, it is possible to avoid a decrease in the visibility of information.

JP 2011-150066 A JP 2011-150065 A

  In recent years, information display devices such as those described above are often required to display a large amount of information within a predetermined size. For this reason, the number of display electrodes and wiring for applying a voltage to the display electrodes is increased, and high integration is required.

  When the information display device is highly integrated, as described above, the visibility of the information can be improved simply by making the formation height of the wiring on the base substrate lower than the formation height of the display electrode and the bank member. It may be insufficient to avoid degradation.

  The present invention has been made in view of the problems of the conventional techniques as described above, and even when the electrode is highly integrated, the visibility by the wiring for applying a voltage to the electrode is improved. An object of the present invention is to provide an information display device capable of avoiding the decrease.

In order to achieve the above object, the present invention provides:
A first electrode layer formed on a base substrate; a second electrode layer disposed opposite to the base substrate of the first electrode layer; the first electrode layer; An information display layer sandwiched between the second electrode layer, the first electrode layer has a plurality of electrodes, or a plurality of electrodes, and a formation height on the base substrate is When the information display layer is viewed from one surface side by selectively applying one of the first and second voltages to the plurality of electrodes, the bank member being the same as the electrode. Information display for displaying different colors in a region of the information display layer facing the electrode to which the first voltage is applied and a region of the information display layer facing the electrode to which the second voltage is applied In the device
Wiring for applying a voltage to the plurality of electrodes is formed on the base substrate, and electrodes or banks other than the electrode to which voltage is applied by the wiring among the plurality of electrodes along both sides of the wiring A member is formed,
The wiring has a formation height on the base substrate that is lower than a formation height on the base substrate at an end portion of the electrode or the bank member along the wiring, and a difference in height is 3 μm or more. ,
In the region along the wiring, the electrode and the bank member have a width of 100 μm or more in a direction orthogonal to the direction in which the wiring extends, and a distance of 410 μm or less without contacting the wiring. It is characterized by.

  In the present invention configured as described above, either one of the first and second voltages is selectively applied to the plurality of electrodes constituting the first electrode layer formed on the base substrate. When the information display layer is viewed from one surface side, the region facing the electrode to which the first voltage of the information display layer is applied faces the electrode to which the second voltage of the information display layer is applied. Different colors are displayed depending on the area. At this time, a color corresponding to the voltage applied to the wiring is also displayed in the area facing the wiring for applying a voltage to the plurality of electrodes. . Therefore, when the voltage applied to the electrodes formed along both sides of the wiring is different from the voltage applied to the wiring, only the region facing the wiring will be displayed in a color different from the surrounding area. . However, the formation height of the wiring on the base substrate is lower than the formation height of the end portion of the electrode along the wiring on the base substrate, and the difference in height is 3 μm or more. The electrode acts like a bank, and the distance between the wiring and the information display layer becomes wider than the distance between the electrode along the both sides of the wiring and the information display layer. Further, in the region where the electrodes are along the wiring, the width of the electrode in the direction orthogonal to the direction in which the wiring extends is 100 μm or more, and the distance between the electrodes is 410 μm or less without the electrodes being in contact with the wiring. When the information display layer is stacked on the first electrode layer, the information display layer may bend in a region where the wiring is formed, and the interval between the wiring and the information display layer cannot be secured. Avoided.

  In addition, when there are no electrodes on both sides of the wiring, bank members are formed along both sides of the wiring. In this configuration, the height of the wiring on the base substrate is the end of the bank member along the wiring. Is lower than the formation height on the base substrate, and the height difference is 3 μm or more, so that the bank members on both sides of the wiring act like a bank, and the distance between the wiring and the information display layer is It becomes wider than the space | interval of the bank member and information display layer along the both sides of wiring. Further, in the region where the bank member is along the wiring, the width of the bank member in the direction orthogonal to the direction in which the wiring extends is 100 μm or more, and the bank member is not in contact with the wiring and the distance between the bank members is 410 μm or less. For this reason, when the information display layer is stacked on the first electrode layer, the information display layer bends in the area where the wiring is formed, and the distance between the wiring and the information display layer cannot be secured. Is avoided.

  In this way, even when the electrode is highly integrated by specifically limiting the formation height of the wiring on the base substrate and the formation conditions of the electrode and bank member, a voltage is applied to the electrode. Therefore, a decrease in visibility due to the wiring for avoiding this is avoided.

  In the present invention, the formation height of the wiring on the base substrate is made lower than the formation height on the base substrate at the end portion of the electrode or bank member along the wiring, and the difference in height is 3 μm or more. Further, in the region along the wiring of the electrode and the bank member, the width in the direction orthogonal to the direction in which the wiring extends is 100 μm or more, and the distance between the electrode and the bank member is 410 μm or less without contacting the wiring. As described above, even when the electrode is highly integrated by specifically limiting the formation height of the wiring on the base substrate and the formation conditions of the electrode and bank member, a voltage is applied to the electrode. It is possible to avoid a decrease in visibility due to the wiring for applying.

It is a figure which shows one Embodiment of the board | substrate for display apparatuses used for the information display apparatus of this invention, (a) is the figure seen from the surface, (b) is AA 'sectional drawing shown to (a). (C) is the A section enlarged view shown in (b). It is a figure which shows the structure of the electrophoretic display used as one Embodiment of the information display apparatus using the electrode substrate for display apparatuses shown in FIG. 1, (a) is the electrode substrate for display apparatuses in FIG.1 (b). Sectional drawing of the area | region corresponded to the part shown, (b) is the A section enlarged view shown to (a). FIG. 3 is a diagram for explaining the influence of the formation height of the wiring on the base substrate in the information display device shown in FIG. 2 on the information display, (a) is a diagram showing the quality of the display state by the width of the wiring; (B) is a figure which shows the result of having measured the difference in the formation height on the base base material with respect to the width | variety of a wiring, a display electrode, and a background electrode. It is a figure which shows the quality of the display state by the width | variety of the background electrode in the area | region along wiring in the information display apparatus shown in FIG. It is a figure which shows the quality of the display state by the space | interval of the area | region which followed the wiring of a background electrode in the information display apparatus shown in FIG. FIG. 3 is a diagram for explaining an operation when displaying “0” on the information display device shown in FIG. 2, (a) is a diagram showing a partial cross section, and (b) is a diagram showing a display state. is there. It is a figure which shows the laminated structure of a general electrophoretic display, (a) is a figure which shows the whole laminated structure, (b) is the A section enlarged view shown to (a).

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a view showing an embodiment of a substrate for a display device used in an information display device of the present invention, where (a) is a view seen from the surface, and (b) is an A-shown in (a). A 'sectional drawing, (c) is the A section enlarged view shown in (b).

  As shown in FIG. 1, the electrode substrate for a display device in the present embodiment has a plurality of display electrodes 11a to 11g constituting the first electrode layer and a display electrode 11a on one surface of a base substrate 14 made of PET or the like. Wirings 12a to 12g for applying a voltage to 11g and one background electrode 13 are formed, and a controller 15 for applying a voltage to the display electrodes 11a to 11g via the wirings 12a to 12g is mounted. It is configured.

  The display electrodes 11a to 11g are formed on one surface of the base substrate 14 in a pattern corresponding to the information displayed. In the present embodiment, numbers are displayed using the display electrodes 11a to 11g. The display electrodes 11a to 11g constitute a display unit including seven segments, and the display electrodes are connected via the wirings 12a to 12g. A voltage is selectively applied to 11a to 11g, and numbers from "0" to "9" can be displayed.

  One end of each of the plurality of wirings 12a to 12g for applying a voltage to the display electrodes 11a to 11g is connected to the display electrodes 11a to 11g, and is then drawn out of the display unit composed of seven segments. Is connected to the controller 15.

  The background electrode 13 is formed on the base substrate 14 so as to fill a region where the display electrodes 11a to 11g and the wirings 12a to 12g are not formed, and the outer periphery of the display electrodes 11a to 11g and the wirings 12a to 12g. Along the both sides, the display electrodes 11a to 11g and the wirings 12a to 12g are formed while maintaining an insulating space.

The display electrodes 11a to 11g and the background electrode 13 have the same formation height on the base substrate 14, and the wirings 12a to 12g have the formation height on the base substrate 14 of the display electrodes 11a to 11a. 11 g and the formation height of the background electrode 13 on the base substrate 14 are lower by h ₁ .

  In the electrode substrate 10 for display devices configured as described above, the display electrodes 11a to 11g, the wirings 12a to 12g, and the background electrode 13 can be formed by printing on the base substrate 14. For example, the display electrodes 11a to 11g, the wirings 12a to 12g, and the background electrode 13 may be printed on the base substrate 14 by screen printing using a conductive paste such as silver paste or carbon paste or conductive ink.

  Below, the information display apparatus using the electrode substrate 1 for display apparatuses comprised as mentioned above is demonstrated.

  FIG. 2 is a diagram showing a configuration of an electrophoretic display which is an embodiment of an information display device using the display device electrode substrate 1 shown in FIG. 1, and (a) shows the display device electrode substrate 1. Sectional drawing of the area | region corresponded to the part shown in FIG.1 (b), (b) is the A section enlarged view shown to (a).

  In the present embodiment, as shown in FIG. 2, the display device electrode substrate 1 is formed on the surface of the display device electrode substrate 1 shown in FIG. 1 on which the display electrodes 11 a to 11 g, the wirings 12 a to 12 g and the background electrode 13 are formed. An information display layer 30 for displaying information according to a voltage applied to the display electrodes 11a to 11g and the background electrode 13 is laminated, and a transparent conductive film substrate 20 is laminated on the information display layer 30. .

  The transparent conductive film substrate 20 is configured by forming a transparent electrode (for example, ITO) 21 serving as a second electrode layer on one surface of a transparent substrate 22 made of glass, transparent film, or the like, and the display electrodes 11a to 11a. 11 g and the background electrode 13 and the transparent electrode 21 are arranged to face each other, and the information display layer 30 is sandwiched between the display electrodes 11 a to 11 g and the background electrode 13 and the transparent electrode 21.

  The information display layer 30 is configured such that the partition wall liquid 32 in which the chargeable particles 33 are dispersed is accommodated in a region surrounded by the partition wall 31 and the seal layer 34. The display device electrode substrate 10, the information display layer 30, and the transparent conductive film substrate 20 are regions in which the transparent electrode 21, the display electrodes 11 a to 11 g, and the background electrode 13 are surrounded by the partition wall 31 and the seal layer 34. Are stacked so as to face each other through the liquid 32 in the partition walls. The partition wall 31 includes a bottom portion, a side portion that is an outer peripheral portion of the information display layer 30, and a wall portion that divides the region surrounded by the side portion into a plurality of regions of, for example, 130 μm □. The surface on the opposite side is open. And it laminates | stacks so that the bottom part side may oppose the electrode substrate 10 for display apparatuses, and the seal layer 34 is laminated | stacked on the opened side.

As described above, in the display device electrode substrate 10, the formation heights of the wirings 12 a to 12 g on the base substrate 14 are the formation heights of the display electrodes 11 a to 11 g and the background electrode 13 on the base substrate 14. although since the lower by h _1, it abuts against the bottom portion of the partition wall 31 of the display electrodes 11a~11g and background electrodes 13 are information display layer 30 than is the wiring 12a~12g the wiring of background electrodes 13 12a to The portions along both sides of 12g act like a bank and are not in contact with the partition wall 31 of the information display layer 30, so that the distance between the wirings 12a to 12g and the information display layer 30 is the display electrodes 11a to 11g. The distance between the background electrode 13 and the information display layer 30 is wider.

  In the information display device 1 configured as described above, the transparent electrode 21 is set to the GND potential, a negative voltage is applied to the background electrode 13 via a wiring (not shown), and the display electrodes 11a to 11g are applied. When a positive or negative voltage is selectively applied via the wirings 12a to 12g, the partition wall liquid 32 accommodated in the region surrounded by the partition wall 31 and the seal layer 34 is made of a dielectric material, and is charged particles. Since 33 is charged at a negative potential, the chargeable particles 33 move in the partition wall liquid 32 by the Coulomb force, and the display electrode to which a negative voltage is applied among the display electrodes 11a to 11g and the background. In the region where the electrode 13 is formed, the chargeable particles 33 are attracted to the transparent electrode 21 side. Similarly, in the region where the display electrode to which a positive voltage is applied is formed among the display electrodes 11a to 11g, the chargeable particles 33 are attracted to the display electrode side.

  When the electrophoretic display is viewed from the transparent conductive film substrate 20 side, the partition wall liquid 32 is colored with a dye or pigment, and the chargeable particles 33 include a light scattering component having a high refractive index. The region where the charged particles 33 are attracted toward the electrodes 11a to 11g, that is, the region facing the display electrode to which a positive voltage is applied among the display electrodes 11a to 11g appears to be colored, and the transparent electrode A region where the chargeable particles 33 are attracted to the side 21, that is, a region facing the background electrode 13 and the display electrode to which a negative voltage is applied among the display electrodes 11a to 11g appears to be white. The desired information colored in is displayed.

  Here, the influence of the wirings 12a to 12g on the information display will be described.

Will be described first impact of which is lower by h ₁ than formed heights on the base substrate 14 of the forming height of the base substrate on 14 of the wiring 12a~12g display electrodes 11a~11g and background electrodes 13 .

  As described above, when a voltage is selectively applied to the display electrodes 11a to 11g via the wirings 12a to 12g, even in a region facing the wirings 12a to 12g of the information display unit 30, as described above, When the chargeable particles 33 are moved by the Coulomb force in the liquid 32 and viewed from the transparent conductive film substrate 20 side, the region where the chargeable particles 33 are attracted to the wirings 12a to 12g side looks colored. In addition, the region where the chargeable particles 33 are attracted to the transparent electrode 21 side appears white, and thus the visibility of information displayed by the display electrodes 11a to 11g is lowered.

However, in this embodiment, since the formed heights of the base substrate on 14 of the wiring 12a~12g is lower by h ₁ than formed heights on the base substrate 14 of the display electrodes 11a~11g and background electrodes 13 The background electrodes 13 on both sides of the wirings 12a to 12g act like a bank, and the distance between the wirings 12a to 12g and the information display layer 30 is the distance between the display electrodes 11a to 11g or the background electrode 13 and the information display layer 30. As a result, the area of the information display layer 30 facing the wirings 12a to 12g is less affected by the voltage applied to the wirings 12a to 12g.

  Here, in the region facing the wirings 12a to 12g of the information display layer 30, the formation height of the wirings 12a to 12g on the base substrate 14 is changed, and the color according to the voltage applied to the wirings 12a to 12g is changed. Evaluated whether it is displayed.

  FIG. 3 is a diagram for explaining the influence of the formation height of the wirings 12a to 12g on the base substrate 14 on the information display in the information display device 1 shown in FIG. The figure which shows the quality of the display state by the width of 12g, (b) is the difference of the formation height on the base substrate 14 of wiring 12a-12g, display electrode 11a-11g, and background electrode 13 with respect to the width of wiring 12a-12g. It is a figure which shows the result of having measured. In FIG. 3A, a case where a color corresponding to the voltage applied to the wirings 12a to 12g is not displayed in a region facing the wirings 12a to 12g of the information display layer 30 is indicated by “◯”. A case where a color corresponding to the voltage applied to the wirings 12a to 12g is displayed is indicated by “x”.

  As shown in FIG. 3A, when the widths of the wirings 12a to 12g are 30 μm and 40 μm, the voltages applied to the wirings 12a to 12g in the region facing the wirings 12a to 12g of the information display layer 30 The color corresponding to was not displayed.

  On the other hand, when the widths of the wirings 12a to 12g are 50 μm and 60 μm, colors corresponding to the voltages applied to the wirings 12a to 12g are displayed in the region facing the wirings 12a to 12g of the information display layer 30. Oops.

  Here, when the display electrodes 11a to 11g and the wirings 12a to 12g are formed on the base substrate 14 by screen printing, since the widths of the wirings 12a to 12g are narrow, the formation height on the base substrate 14 is Depends on its width.

  Therefore, when the difference in formation height on the base substrate 14 between the wirings 12a to 12g, the display electrodes 11a to 11g, and the background electrode 13 with respect to the width of the wirings 12a to 12g is measured, as shown in FIG. When the width of the wirings 12a to 12g is 30 μm, the height difference is about 5 μm to 6.5 μm, and when the width of the wirings 12a to 12g is 40 μm, the height difference is about 3 μm to 5 μm. When the width of 12 g is 50 μm, the height difference is about 1.5 μm to 3 μm, and when the width of the wirings 12 a to 12 g is 60 μm, the height difference is about 0.5 μm to 2.5 μm. .

On the base substrate 14 of the display state shown in FIG. 3A and the wirings 12a to 12g, the display electrodes 11a to 11g and the background electrode 13 corresponding to the widths of the wirings 12a to 12g shown in FIG. In view of the measurement result of the difference in formation height in the case where the difference in formation height h ₁ on the base substrate 14 between the wirings 12a to 12g, the display electrodes 11a to 11g, and the background electrode 13 is 3 μm or more, information In a region facing the wirings 12a to 12g of the display layer 30, a color corresponding to the voltage applied to the wirings 12a to 12g is not displayed.

When the display electrodes 11a to 11g and the background electrode 13 are formed by screen printing using a conductive ink in the electrode substrate 10 for the display device shown in FIG. 1, the display electrodes 11a to 11g and the background electrode 13 are formed. In the mesh portion of the plate, the conductive ink acts so as to be adsorbed on the side surface of the emulsion portion. As a result, as shown in FIG. 1C, the edge portions of the display electrodes 11a to 11g and the background electrode 13 Will be excited. Therefore, strictly speaking, the difference in height h ₁ between the wirings 12 a to 12 g and the display electrodes 11 a to 11 g and the background electrode 13 on the base substrate 14 is the wiring 12 a to 12 g and the wirings 12 a to 12 g of the background electrode 13. Is the difference in the formation height on the base substrate 14 from the end along the line.

In the information display device 1 as shown in FIG. 2, the information display layer 30 and the transparent conductive film substrate 20 are laminated and laminated on the display device electrode substrate 10 shown in FIG. Even if the difference in height h ₁ on the base substrate 14 between the ends of the wirings 12a to 12g and the background electrodes 13 along the wirings 12a to 12g on the base substrate 14 is 3 μm or more as described above, information is generated by the external force due to lamination. There is a possibility that the display layer 30 may bend and the interval between the wirings 12a to 12g and the information display layer 30 cannot be secured.

Therefore, the width w ₁ of the background electrode 13 in the region along the wirings 12a to 12g and the interval w ₂ of the region along the wirings 12a to 12g of the background electrode 13 are changed as shown in FIG. Then, it was evaluated whether or not a color corresponding to the voltage applied to the wirings 12a to 12g was displayed due to the bending of the information display layer 30.

  FIG. 4 is a diagram showing the quality of the display state depending on the width of the background electrode 13 in the region along the wirings 12a to 12g in the information display device 1 shown in FIG. FIG. 5 is a diagram showing the quality of the display state according to the distance between the areas along the wirings 12a to 12g of the background electrode 13 in the information display device 1 shown in FIG. 4 and 5, “◯” indicates a case where a color corresponding to the voltage applied to the wirings 12 a to 12 g is not displayed in a region facing the wirings 12 a to 12 g of the information display layer 30. A case where a color corresponding to the voltage applied to the wirings 12a to 12g is displayed is indicated by “x”.

In this evaluation, the formation height of the wirings 12a to 12g on the base substrate 14 is 7 μm, and the wirings 12a to 12g and the end portions of the background electrode 13 along the wirings 12a to 12g on the base substrate 14 are used. The difference in formation height h ₁ was 6 μm.

As shown in FIG. 4, in the information display device 1 shown in FIG. 2, when the width w ₁ of the background electrode 13 in the region along the wirings 12 a to 12 g is 80 μm, the wirings 12 a to 12 g of the information display layer 30. A color corresponding to the voltage applied to the wirings 12a to 12g has been displayed in the region opposite to. Incidentally, the width w ₁ of the background electrode 13 in the region along the line 12a to 12g is the width of the background electrode 13 in the direction perpendicular to the direction in which the wires 12a to 12g extend in a region along the line 12a to 12g.

On the other hand, when the width w ₁ of the background electrode 13 in the region along the wirings 12a to 12g is 100 μm and 200 μm, it is applied to the wirings 12a to 12g in the region facing the wirings 12a to 12g of the information display layer 30. The color corresponding to the voltage was not displayed.

As shown in FIG. 5, when the distance w ₂ between the regions along the background electrode 13 via the wirings 12 a to 12 g in the information display device 1 shown in FIG. 2 is 350 μm to 410 μm, the wiring of the information display layer 30 A color corresponding to the voltage applied to the wirings 12a to 12g was not displayed in the region facing 12a to 12g.

On the other hand, in the information display device 1 shown in FIG. 2, when the interval w ₂ between the regions along the wirings 12 a to 12 g of the background electrode 13 is 420 μm, the wiring is formed in the region facing the wirings 12 a to 12 g of the information display layer 30. The color corresponding to the voltage applied to 12a-12g has been displayed.

As a result, the width w ₁ in the direction orthogonal to the direction in which the background electrode 13 extends in the region along the wirings 12 a to 12 g is 100 μm or more, and the interval w ₂ between the regions along the wirings 12 a to 12 g. Is 410 μm or less, when the information display layer 30 and the transparent conductive film substrate 20 are laminated and laminated on the display device electrode substrate 10 shown in FIG. In addition, the distance between the wirings 12a to 12g and the information display layer 30 can no longer be secured, and the color corresponding to the voltage applied to the wirings 12a to 12g in the region of the information display layer 30 facing the wirings 12a to 12g. Will be prevented from being displayed. The distance between the regions of the background electrode 13 along the wirings 12a to 12g may be 410 μm or less, but the background electrode 13 and the wirings 12a to 12g are not in contact with each other, and an insulating space is maintained between them. Needless to say, it is necessary to keep it.

  Hereinafter, an operation in the case where “0” is displayed using the seven segments shown in FIG. 1 in the information display device 1 described above will be described.

  6A and 6B are diagrams for explaining an operation when displaying “0” in the information display device 1 shown in FIG. 2, in which FIG. 6A is a diagram showing a partial cross section, and FIG. It is a figure which shows a state.

  When "0" is displayed on the information display device 1 shown in FIG. 2, the transparent electrode 21 is set to the GND potential, a negative voltage is applied to the display electrode 11g and the background electrode 13, and a positive voltage is applied to the display electrodes 11a to 11e. Apply a voltage of.

  Then, as described above, the chargeable particles 33 of the information display layer 30 move by the Coulomb force in the partition wall liquid 32, and the background electrode 13 to which a negative voltage is applied is formed as shown in FIG. In the formed region, the chargeable particles 33 are attracted to the transparent electrode 21 side. Similarly, in the region where the display electrode 11g to which a negative voltage is applied is formed, the chargeable particles 33 are attracted to the transparent electrode 21 side.

  On the other hand, in the region where the display electrodes 11a to 11e to which a positive voltage is applied are formed, the chargeable particles 33 are attracted toward the display electrodes 11a to 11e.

  Thereby, when the information display device 1 is viewed from the transparent conductive film substrate 20 side, the region where the chargeable particles 33 are attracted to the display electrodes 11a to 11e, that is, the region facing the display electrodes 11a to 11e is colored. The region where the chargeable particles 33 are attracted to the transparent electrode 21 side, that is, the region facing the display electrode 11g and the background electrode 13 appears white, and as shown in FIG. Thus, in the white background 3, “0” that is information 2 in a colored state can be seen.

  Here, since the region of the information display layer 30 facing the wirings 12a to 12g is not easily affected by the voltage applied to the wirings 12a to 12g as described above, it depends on the voltage applied to the wirings 12a to 12g. In other words, the chargeable particles 33 are dispersed in the partition wall liquid 32, whereby the information display device 1 is placed in the transparent conductive film substrate in a region facing the wirings 12a to 12g of the information display layer 30. When viewed from the 20th side, it appears to be an intermediate color between white and a colored color. In this way, when the region facing the wirings 12a to 12g appears to be an intermediate color between white and a colored color, the colored color can be seen between the white-looking regions, or the white can be seen between the colored-looking regions. It is avoided that the visibility is lowered by the wirings 12a to 12g.

  As described above, in this embodiment, the formation height of the wirings 12a to 12g on the base substrate 14 is made lower than the formation height of the end portion of the background electrode 13 along the wirings 12a to 12g on the base substrate 14; Further, as a specific numerical value thereof, the width of the background electrode 13 in the direction orthogonal to the direction in which the wiring extends is set to 100 μm or more in the region where the background electrode 13 extends along the wirings 12a to 12g, and The wiring for applying a voltage to the display electrodes 11a to 11g even when the high integration of the electrodes is achieved by setting the interval to 410 μm or less without the background electrode 13 being in contact with the wirings 12a to 12g. Visibility degradation due to 12a to 12g can be avoided.

  In this embodiment, the case where the background electrode 13 is formed along both sides of the wirings 12a to 12g has been described as an example. However, in the configuration without the background electrode 13, two adjacent electrodes are formed. The present invention can also be applied to a configuration in which wirings connected to other display electrodes are formed between display electrodes. In such a configuration, the same color is displayed in a region facing two adjacent display electrodes of the information display layer, and the display electrode connected to the wiring formed between the two display electrodes When a different color is displayed, a line of a color different from the color displayed in the region facing the two display electrodes is displayed between the two display electrodes. Therefore, the difference between the formation height of the wiring on the base substrate and the formation height of the display electrode is as described above, and the width of the display electrode and the interval between the display electrodes via the wiring are as described above. By doing so, it is difficult to be affected by the voltage applied to the wiring in the region facing the wiring of the information display layer, and it is possible to avoid a decrease in visibility.

  Further, in the present embodiment, the formation height on the base substrate 14 of the wirings 12a to 12g for applying a voltage to the display electrodes 11a to 11g, and the width and interval of the background electrode 13 in the region along the wirings 12a to 12g. Although defined, the wiring for applying a voltage to the background electrode 13 may have the same configuration as described above. That is, in a configuration in which a wiring for applying a voltage to the background electrode 13 is formed between the adjacent display electrodes 11a to 11g, there is a difference between the formation height of the wiring on the base substrate and the formation height of the display electrode. As described above, if the width of the display electrode and the interval between the display electrodes via the wiring are as described above, the information is applied to the wiring in the region facing the wiring of the information display layer. It becomes difficult to be affected by the voltage, and the visibility can be prevented from being lowered.

  In addition, in a configuration in which the background electrode is not provided, in the case where the display electrode is formed in an island shape, a bank member that is not applied with a voltage made of a dummy electrode, a resin, or the like is provided along both sides of the wiring. In addition, the difference between the formation height of the wiring on the base substrate and the formation height of the bank member is as described above, the width of the bank member, and the wiring By setting the interval between the bank members via the above-described distance, the area of the information display layer facing the wiring is less affected by the voltage applied to the wiring, and the visibility is reduced. You can avoid that.

  Further, in the present embodiment, the case where white and colored colors are displayed according to the voltage applied to the display electrodes 11a to 11g has been described as an example, but the display electrodes 11a to 11g are applied. The colors displayed according to the voltage are not limited to these colors as long as they are two colors that can be distinguished from each other.

  In this embodiment, as the information display layer 30, the chargeable particles 33 dispersed in the partition wall liquid 32 are applied to the display electrodes 11 a to 11 i and the background electrode 13 by applying voltage to the display electrodes 11 a to 11 g and the background electrode 13. The vertical electrophoretic thin display member that moves to the transparent electrode 21 side and switches the display has been described as an example, but the information display layer 30 displays information by applying a voltage by the display electrode. As long as it has an information display layer, a cholesteric liquid crystal or an electronic powder type can be applied as appropriate.

DESCRIPTION OF SYMBOLS 1 Information display apparatus 2 Information 3 Background 10 Electrode board | substrate for display apparatuses 11a-11g Display electrode 12a-12g Wiring 13 Background electrode 14 Base base material 15 Controller 20 Transparent conductive film substrate 21 Transparent electrode 22 Transparent substrate 30 Information display layer 31 Partition 32 Liquid in partition wall 33 Chargeable particle 34 Seal layer

Claims (1)

A first electrode layer formed on a base substrate; a second electrode layer disposed opposite to the base substrate of the first electrode layer; the first electrode layer; An information display layer sandwiched between the second electrode layer, the first electrode layer has a plurality of electrodes, or a plurality of electrodes, and a formation height on the base substrate is When the information display layer is viewed from one surface side by selectively applying one of the first and second voltages to the plurality of electrodes, the bank member being the same as the electrode. Information display for displaying different colors in a region of the information display layer facing the electrode to which the first voltage is applied and a region of the information display layer facing the electrode to which the second voltage is applied In the device
Wiring for applying a voltage to the plurality of electrodes is formed on the base substrate, and electrodes or banks other than the electrode to which voltage is applied by the wiring among the plurality of electrodes along both sides of the wiring A member is formed,
The wiring has a formation height on the base substrate that is lower than a formation height on the base substrate at an end portion of the electrode or the bank member along the wiring, and a difference in height is 3 μm or more. ,
In the region along the wiring, the electrode and the bank member have a width of 100 μm or more in a direction orthogonal to the direction in which the wiring extends, and a distance of 410 μm or less without contacting the wiring. An information display device.

Images