JP5600278B2 - Bar code display medium - Google Patents

Description

  The present invention relates to a barcode display medium for displaying a barcode, and more particularly to a technique for improving barcode reading accuracy when a mask layer is provided on the surface.

  Conventionally, barcodes have been used to manage articles. This barcode represents identification information with the width and interval of a plurality of black lines with white as a background, and the identification information can be recognized by reading it with a barcode reader. Such a barcode is used by being directly printed on an article or printed on a label and attached to the article. Therefore, once the barcode that has been printed cannot be changed, if you want to change the barcode, you must reprint the barcode on the article or re-apply the label with the modified barcode printed. Don't be.

  Therefore, an information display panel that arranges a display medium whose state changes according to an applied potential between opposing electrodes and displays information by changing the state of the display medium using the potential applied to the electrode. A technique for displaying a bar code using an image has been considered (for example, see Patent Document 1). In this information display panel, by arranging a plurality of electrodes having the width of the narrowest bar among the bars constituting the barcode in the width direction and selectively applying a potential to the plurality of electrodes, The state of the area of the display medium facing the electrode is changed, and white lines are used as a background, and black lines are displayed with a width and an interval corresponding to the information to be displayed.

  In the case of displaying a barcode using the information display panel as described above, in order to display the barcode, a potential is selectively applied to the plurality of electrodes. Wiring and connection terminals for applying a potential need to be connected. Then, depending on the potential applied to the electrode, the state of the region of the display medium facing the electrode changes to display white or black, so that the wiring or connection connected to the electrode of the display medium Even in the region facing the terminal, the state of the display medium changes according to the applied potential, and a black line is displayed in the white background region.

  Therefore, a mask layer is provided by printing or the like on the surface of the region where the wiring and connection terminals as described above are provided, so that the state of the region facing the wiring and connection terminals of the display medium is applied. Even if it is a case where it changes with electric potential, it is performed that it is visually recognized.

JP 2006-234911 A

  In the bar code as described above, in order to identify that the bar arrangement by the black line is a bar code, the narrow bar 10 of the narrowest bar among the bars constituting the bar code is arranged outside the bar arrangement direction. A blank area called a quiet zone having a width more than double is provided.

  However, when the mask layer as described above is provided, the edge portion of the mask layer is recognized as a bar even if the mask layer is provided more than 10 times the narrow bar outside the outermost bar of the bar code. As a result, the bar code reading accuracy is lowered. In particular, when an infrared laser type barcode reader is used, the barcode may not be read. For this reason, when the mask layer is provided, it is necessary to make the width of the quiet zone considerably wide, thereby increasing the size of the entire barcode display medium for displaying the barcode.

  The present invention has been made in view of the problems of the conventional techniques as described above, and accurately reads a barcode without increasing the size of the whole even when a mask layer is provided on the surface. An object of the present invention is to provide a barcode display medium that can be used.

In order to achieve the above object, the present invention provides:
A first electrode layer composed of a plurality of strip-shaped electrodes disposed on one surface side of the base substrate, a second electrode layer formed on the transparent substrate and disposed opposite to the first electrode layer, and an information display layer sandwiched between the second electrode layer and the first electrode layer, wherein the information corresponding to the potential difference between the plurality of strip-shaped electrode and the second electrode layer Information expressed by the bar having the first color with the second color as a background by visually recognizing the first color and the second color by the display layer from the second electrode layer side. In a barcode display medium that displays barcodes arranged in a plurality in the width direction with a width and interval according to
A mask layer provided on a part of the transparent substrate so that the barcode can be visually recognized, and having a linear edge portion parallel to a plurality of bars to be displayed at an end on the side where the barcode is visually recognized. Have
The mask layer is from 2 bars to be aligned direction outermost of said plurality of bar arrangement direction outside of the 10 to 29-fold by the plurality of bars of a width narrowest bar width of the plurality of bars It is provided at a distance, and is composed of colors having a value of (lightness L *) + (chromaticity a *) + (chromaticity b *) of 74 or less.

  In the present invention configured as described above, a plurality of strip electrodes disposed on one surface side of the base substrate and a second electrode disposed opposite to the first electrode layer composed of the plurality of strip electrodes. The first color and the second color by the information display layer sandwiched between the first electrode layer and the second electrode layer are changed to the second electrode layer side according to the potential difference with the electrode layer. By using the second color as a background, a bar having the first color is arranged in the width direction with a width and an interval corresponding to the information to be expressed. Will be displayed. Here, in order to avoid a color on the part of the transparent substrate on which the second electrode layer is formed from being visually recognized due to a change in state in a region facing the wiring or connection terminal of the information display layer Although a mask layer is provided, this mask layer is 10 to 29 times the width of the narrowest bar among the plurality of bars from the two outermost bars in the arrangement direction of the plurality of bars to be displayed. Are arranged apart from each other in the arrangement direction of the plurality of bars, and are configured such that (lightness L *) + (chromaticity a *) + (chromaticity b *) has a value of 74 or less. By configuring the color of the mask layer in this way, the mask layer has the width of the narrowest bar among the plurality of bars from the two outermost bars in the arrangement direction of the plurality of bars to be displayed. If it is provided 10 times or more apart from the outside in the arrangement direction of the plurality of bars, the edge portion of the mask layer will not be recognized as a bar.

  As described above, in the present invention, in order to prevent the color due to the change of the state in the region facing the wiring and connection terminal of the information display layer from being visually recognized, the transparent on which the second electrode layer is formed The mask layer provided on a part of the substrate is 10 to 29 times the width of the narrowest bar among the plurality of bars from the two outermost bars in the arrangement direction of the displayed bars. Since the plurality of bars are provided apart from each other in the arrangement direction, and the mask layer is composed of colors having a value of (lightness L *) + (chromaticity a *) + (chromaticity b *) of 74 or less. The two bars that are the outermost in the arrangement direction of the plurality of bars to be displayed are separated from the outermost direction of the plurality of bars by 10 times the width of the narrowest bar among the plurality of bars. The edge of the mask layer is recognized as a bar. Prevents the put away, can read the whole even if the mask layer provided on the surface exactly the bar code without increasing the size of.

It is a figure which shows an example of the barcode displayed by the barcode display medium of this invention. It is a figure which shows the structure of the wiring electrode board | substrate used for one Embodiment of the barcode display medium of this invention, (a) is the figure seen from the surface, (b) is AA 'shown to (a). It is sectional drawing. It is a figure which shows the structure of the barcode display medium using the wiring electrode board | substrate shown in FIG. 2, (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). FIG. 4 is a diagram for explaining an operation when the barcode shown in FIG. 1 is displayed by the barcode display medium shown in FIG. 3, wherein (a) is a chargeable particle due to a potential difference between a strip electrode and a transparent electrode. FIG. 4B is a diagram showing how the barcode display medium is seen from the transparent conductive film substrate side. FIG. 5 is a diagram for explaining a mask printing color for improving barcode reading accuracy in the barcode display medium shown in FIGS. 3 and 4.

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

  First, the barcode displayed by the barcode display medium of the present invention will be described.

  FIG. 1 is a diagram showing an example of a barcode displayed by the barcode display medium of the present invention.

  As shown in FIG. 1, the barcode in this example has a background portion 4 having a white color as a second color as a background and a plurality of bars 5 having a black color as a first color in the width direction. The bar code symbol unit 2 is arranged side by side and includes a bar code symbol unit 2 for expressing information, and a quiet zone 3 arranged on both sides of the bar code symbol unit 2.

  In the barcode symbol part 2, a plurality of bars 5 are arranged on the background part 4 in the width direction with a width and an interval corresponding to information expressed by the barcode 1. The bar code symbol part 2 includes a start code, a stop code, and a region expressing a check digit.

  The quiet zone 3 is composed only of the white background portion 4 and is arranged on the outer side in the arrangement direction of the bars 5 of the barcode symbol portion 2.

  2A and 2B are diagrams showing a configuration of a wiring electrode substrate used in an embodiment of the barcode display medium of the present invention, where FIG. 2A is a diagram seen from the surface, and FIG. 2B is a diagram shown in FIG. It is AA 'sectional drawing. The wiring electrode substrate 10 shown in FIG. 2 is used for a barcode display medium for displaying the barcode 1 shown in FIG.

  As shown in FIG. 2, the wiring electrode substrate in the present embodiment is formed by forming a plurality of strip electrodes 12 constituting the first electrode layer side by side in the width direction on one surface of the base substrate 11. Two marginal electrodes 15 are formed on the outer side in the arrangement direction, and a connection terminal 14 is connected to each of the strip-shaped electrode 12 and the marginal electrode 15 via a wiring 13. The blank electrode 15 is for displaying the quiet zone 3, and the quiet zone 3 is composed only of the white background portion 4, and therefore has a width of the quiet zone 3 or a width of 1 or more. It has become one by one. Each of the plurality of strip-shaped electrodes 12 is for displaying the barcode symbol part 2 and includes the above-described portions representing the start code, stop code and check digit in the barcode symbol part 2. Among the bars 5 displayed, the width of the narrowest bar (hereinafter referred to as a narrow bar) is the same.

  3A and 3B are diagrams showing the configuration of a bar code display medium using the wiring electrode substrate 10 shown in FIG. 2, wherein FIG. 3A is a view seen from the surface, and FIG. A 'sectional drawing, (c) is the A section enlarged view shown in (b).

  As shown in FIG. 3, the bar code display medium in the present embodiment has an information display layer 20 and a transparent conductive film substrate 30 on the surface of the wiring electrode substrate 10 shown in FIG. And are laminated. The transparent conductive film substrate 30 is configured by forming a transparent electrode (for example, ITO) 32 serving as a second electrode layer on one surface of a transparent substrate 31 made of glass or the like, and the information display layer 20 includes In the region surrounded by the partition wall 21 and the seal layer 24, the partition wall liquid 22 in which the chargeable particles 23 are dispersed is accommodated. The wiring electrode substrate 10, the information display layer 20, and the transparent conductive film substrate 30 are accommodated in a region where the transparent electrode 32, the strip electrode 12, and the blank electrode 15 are surrounded by the partition wall 21 and the seal layer 24. They are stacked so as to face each other with the liquid 22 in the partition walls interposed therebetween. The partition wall 21 includes a bottom portion, a side portion that is an outer peripheral portion of the information display layer 20, and a wall portion that divides the region surrounded by the side portion into a plurality of regions, and is on the side opposite to the bottom portion. The surface is open. And it laminates | stacks so that the bottom part side may oppose the transparent conductive film substrate 30, and the sealing layer 24 is laminated | stacked on the opened side.

  The transparent conductive film substrate 30 is laminated on the side opposite to the strip electrode 12 of the information display layer 20, and on the transparent substrate 31, a part of the margin electrode 15 on the outside in the alignment direction with the strip electrode 12. A mask layer is provided by mask printing 33 so as to surround the belt-like electrode 12 and the blank electrode 15 while overlapping with each other. Thereby, the wiring 13 and the connection terminal 14 formed on the wiring electrode substrate 10 are not visually recognized through the transparent light conductive film substrate 30.

  Hereinafter, the barcode display by the barcode display medium 6 configured as described above will be described.

  FIG. 4 is a diagram for explaining the operation when displaying the barcode 1 shown in FIG. 1 by the barcode display medium 6 shown in FIG. 3, and (a) shows the strip-like electrode 12, the transparent electrode 32, and the like. FIG. 6B is a diagram showing the movement of the chargeable particles 23 due to the potential difference between them, and FIG. 7B is a diagram showing how the barcode display medium 6 is seen from the transparent conductive film substrate 30 side.

  When the barcode 1 shown in FIG. 1 is displayed by the barcode display medium 6 shown in FIG. 3, for example, the transparent electrode 32 is set to 0 V, and the strip electrode 12 and blank electrode 15 formed on the base substrate 11 are used. Among them, a positive voltage is applied to the blank electrode 15 for displaying the quiet zone 3 and the strip electrode 12 for displaying the background portion 4 according to the information desired to be expressed in the barcode symbol portion 2, A negative voltage is applied to the strip electrode 12 for displaying the bar 5 in accordance with the information desired to be expressed in the barcode symbol part 2. This is performed by selectively applying a positive or negative voltage to the connection terminal 14 connected to the strip electrode 12 or the blank electrode 15 via the wiring 13.

  As described above, when the transparent electrode 32 is set to 0 V and a positive or negative voltage is applied to the strip electrode 12 and the blank electrode 15, the transparent electrode 32 faces the strip electrode 12 and the blank electrode 15 to which a positive voltage is applied. In the region, there is a potential difference in which the transparent electrode 32 side is negative with respect to the strip electrode 12, and in the region facing the strip electrode 12 to which a negative voltage is applied, the transparent electrode 32 side is in relation to the strip electrode 12. A positive potential difference occurs. Then, since the partition wall liquid 22 accommodated in the region surrounded by the partition wall 21 and the seal layer 24 is made of a dielectric material, and the chargeable particles 23 are charged to a positive potential, FIG. ), In a region facing the strip electrode 12 to which a negative voltage is applied, the chargeable particles 23 are attracted toward the strip electrode 12, and the strip electrode 12 to which a positive voltage is applied. In the region facing the blank electrode 15, the chargeable particles 23 are attracted toward the transparent electrode 32.

  The partition wall liquid 22 is colored black with a dye or pigment, and the chargeable particles 23 contain a light scattering component having a high refractive index. Therefore, the barcode display medium 6 is viewed from the transparent conductive film substrate 30 side. In this case, in the region facing the strip electrode 12 to which a negative voltage is applied, the black color by the information display layer 20 is recognized through the transparent conductive film substrate 30, and the strip electrode 12 to which a positive voltage is applied and In the region facing the blank electrode 15, the white color due to the information display layer 20 is recognized through the transparent conductive film substrate 30.

  In the barcode symbol part 2, the width of the strip electrode 12 is the same as the width of the narrow bar among the bars 5 displayed in the barcode symbol part 2 as described above. When the width of the bar 5 displayed in black in the portion 2 is the same as the width of the strip electrode 12, a negative voltage is applied to one strip electrode 12 and the strip electrode 12 adjacent to the strip electrode 12 is applied. In addition, when the width of the bar 5 displayed in black in the barcode symbol part 2 is twice the width of the strip electrode 12, a negative voltage is applied to the two adjacent strip electrodes 12. When a voltage is applied, a positive voltage is applied to the adjacent strip electrodes 12 on both sides of the two strip electrodes 12, and the width of the bar 5 displayed in black in the bar code symbol portion 2 is When the width of the electrode 12 is three times, a negative voltage is applied to the three adjacent strip electrodes 12 and a positive voltage is applied to the adjacent strip electrodes 12 on both sides of the three strip electrodes 12. It will be. Similarly, for the background portion 4, when the interval between the two bars 5 displayed in the bar code symbol portion 2 is the same as the width of the strip electrode 12, a positive voltage is applied to one strip electrode 12. In addition, a negative voltage is applied to the strip electrode 12 adjacent to the strip electrode 12, and the interval between the two bars 5 displayed in the barcode symbol part 2 is twice the width of the strip electrode 12. In this case, a positive voltage is applied to the two adjacent strip electrodes 12 and a negative voltage is applied to the adjacent strip electrodes 12 on both sides of the two strip electrodes 12. When the interval between the two bars 5 to be displayed is three times the width of the strip electrode 12, a positive voltage is applied to the three adjacent strip electrodes 12, and both sides of the three strip electrodes 12 are applied. Negative voltage is to be applied to the strip-shaped electrodes 12 in contact.

  In this way, a positive or negative voltage is applied to the belt-like electrode 12 in accordance with the width and interval of the bar 5 displayed in black in the bar code symbol portion 2, so that the bar code display medium 6 is made into a transparent conductive film substrate. When viewed from the side 30, as shown in FIG. 4B, in the barcode symbol part 2, a background part 4 having white is used as a background, and a plurality of bars 5 having black are provided in the width direction. The barcodes 1 arranged side by side are recognized, and only the white background portion 4 is recognized in the quiet zone 3. At this time, the plurality of strip electrodes 12 to which the same voltage is applied according to the width and interval of the bar 5 in the barcode symbol part 2 are arranged side by side at a minute interval. When the same voltage is applied to 12, the minute interval is not recognized, and when the same voltage is applied to two adjacent strip electrodes 12, the bar 5 or the background portion 4 having a width twice that of the strip electrode 12. When the same voltage is applied to the three adjacent strip electrodes 14, the bar 4 or the background portion 4 having a width three times that of the strip electrode 12 is recognized.

  In the information display layer 20, the chargeable particles 23 are applied to the wiring 13, the connection terminal 14, or the transparent electrode 32 according to the voltage applied to the strip electrode 12 even in the region facing the wiring 13 and the connection terminal 14. When the barcode display medium 6 is viewed from the transparent conductive film substrate 30 side, the black or white color is recognized by the drawing, but the region surrounding the strip electrode 12 and the blank electrode on the transparent substrate 32. Since the mask printing 33 is applied to this, it is avoided that the mask printing 33 visually recognizes a color due to a change in state in a region facing the wiring 13 and the connection terminal 14 of the information display layer 20.

  Below, the mask printing 33 performed on the transparent substrate 32 is demonstrated.

  As described above, the mask printing 33 overlaps a part of the transparent conductive film substrate 30 on the transparent substrate 32 that is outside the alignment direction of the blank electrode 15 with the strip electrode 12 while overlapping the strip electrode 12 and the blank electrode 15. It is given to surround. Then, as shown in FIG. 4B, in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2, 10 to 29 times the width of the narrow bar from the two outermost bars in the arrangement direction. Only a plurality of bars 5 are provided away from each other in the arrangement direction.

  FIG. 5 is a diagram for explaining the colors of the mask print 33 for improving the reading accuracy of the barcode 1 in the barcode display medium 6 shown in FIGS. 3 and 4.

  In the barcode display medium 6 shown in FIGS. 3 and 4, the area to be subjected to the mask printing 33 is changed from the two outermost bars in the arrangement direction of the plurality of displayed bars 5 to the outside, thereby performing the mask printing. The bar code 1 readability of 33 colors was measured. In this measurement, an infrared laser type bar code reader was used.

  In the case where the mask printing 33 is performed in black as Example 1, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol part 2. The barcode 1 could be read in all cases where the width was 10 to 40 times the width of the narrow bar outward in the direction. The black color used in this example has L * (lightness) of 23.78, a * (chromaticity) of 0.04, and b * (chromaticity) of −0.1. The value added with is 23.72. L * a * b defined in the present invention is according to JIS Z 8729.

  When the mask printing 33 is performed in blue as the second embodiment, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2 to the arrangement of the plurality of bars 5. The barcode 1 could be read in all cases where the width was 10 to 40 times the width of the narrow bar outward in the direction. The blue color used in this example has L * (lightness) of 37.1, a * (chromaticity) of 0.65, and b * (chromaticity) of −46.49. The value obtained by adding is −8.74.

  In the case where the mask printing 33 is performed in a blue (thin) color as the third embodiment, the mask printing 33 includes a plurality of bars from the outermost two bars in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol part 2. The barcode 1 could be read in all cases where the bar 5 was 10 to 40 times wider than the width of the narrow bar outside the arrangement direction. Note that the blue (light) color used in this example is 50.17 for L * (lightness), -2.82 for a * (chromaticity), and -38.55 for b * (chromaticity). Yes, the sum of these vectors is 8.8.

  In the case where the mask printing 33 is performed in green as the fourth embodiment, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2. The barcode 1 could be read in all cases where the width was 10 to 40 times the width of the narrow bar outward in the direction. The green color used in this example has L * (lightness) of 53.39, a * (chromaticity) of −42.03, and b * (chromaticity) of 33.51. The value obtained by adding is 44.87.

  In the case where the mask printing 33 is applied in gray (dark) as the fifth embodiment, the mask printing 33 includes a plurality of bars from the outermost two bars in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2. The barcode 1 could be read in all cases where the bar 5 was 10 to 40 times wider than the width of the narrow bar outside the arrangement direction. The gray (dark) used in this example has L * (brightness) of 56.28, a * (chromaticity) of 0.19, and b * (chromaticity) of -0.39. The value obtained by adding these vectors is 56.08.

  When the mask print 33 is applied in gray (thin) as the sixth embodiment, the mask print 33 is displayed on the bar code symbol 2 from the two bars that are the outermost in the arrangement direction of the plurality of bars 5. The bar code 1 could be read in all cases where the width of the narrow bar was 10 to 40 times as large as the width of the narrow bar. Note that the gray (thin) used in this example has L * (lightness) of 63.18, a * (chromaticity) of 0.27, and b * (chromaticity) of −0.34. The value obtained by adding these vectors is 63.11.

  When the mask printing 33 is applied in gray (ultra-thin) as the seventh embodiment, the mask printing 33 is generated from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol part 2. The barcode 1 could be read in all cases where the bar 5 was 10 to 40 times wider than the width of the narrow bar outside the arrangement direction. Note that the gray (ultra-thin) used in this example has L * (lightness) of 73.85, a * (chromaticity) of 0.35, and b * (chromaticity) of -0.24. The value obtained by adding these vectors is 73.96.

  In the case where the mask printing 33 is applied in light blue as the eighth embodiment, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol part 2. The barcode 1 could be read in all cases where the width was 10 to 40 times the width of the narrow bar outward in the direction. The light blue used in this example has L * (lightness) of 79.01, a * (chromaticity) of -0.62, and b * (chromaticity) of -7.22. The value obtained by adding the vector is 71.17.

  On the other hand, when the mask printing 33 is applied in pink as Comparative Example 1, the mask printing 33 is changed from the two bars that are the outermost in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2 to the plurality of bars. Bar code 1 could not be read when the width of the narrow bar was 10 to 29 times apart from the width of 5 in the arrangement direction, and bar code 1 could be read when it was 30 times or more apart. The pink color used in this example has L * (lightness) of 40.65, a * (chromaticity) of 62.76, and b * (chromaticity) of −1.87. The value added with the vector is 101.54.

  When the mask printing 33 is performed in red as Comparative Example 2, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2 to the arrangement of the plurality of bars 5. Barcode 1 could not be read when the width was 10 to 30 times the width of the narrow bar on the outside in the direction, and barcode 1 could be read when it was 35 or 40 times apart. The red color used in this example has L * (lightness) of 40.35, a * (chromaticity) of 52.66, and b * (chromaticity) of 38.24. The added value is 131.25.

  When the mask print 33 is applied in brown as Comparative Example 3, the mask print 33 is arranged from the two bars that are the outermost in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2. Barcode 1 could not be read when the width was 10 to 30 times the width of the narrow bar on the outside in the direction, and barcode 1 could be read when it was 35 or 40 times apart. The brown color used in this example has L * (lightness) of 64.83, a * (chromaticity) of 13.71, and b * (chromaticity) of 65.87. The added value is 144.41.

  When the mask printing 33 is performed in yellow as Comparative Example 4, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed in the barcode symbol part 2 to the arrangement of the plurality of bars 5. Bar code 1 could not be read when it was 10 to 35 times the width of the narrow bar outward in the direction, and bar code 1 could be read when it was 40 times away. The yellow color used in this example has L * (lightness) of 85.6, a * (chromaticity) of -16.76, and b * (chromaticity) of 88.69. The value obtained by adding is 157.53.

  When the mask printing 33 is performed in white as the comparative example 5, the mask printing 33 is arranged from the two outermost bars in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol part 2. Bar code 1 could not be read when it was 10-29 times the width of the narrow bar on the outer side in the direction, and bar code 1 could be read when it was 30 times or more apart. The white color used in this example has L * (lightness) of 89.42, a * (chromaticity) of 0.57, and b * (chromaticity) of −1.02, and these vectors The value added with is 88.97.

  Based on the measurement results described above, in order to reduce the size of the barcode display medium 6, a plurality of bars including the two outermost bars in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol portion 2 and the mask printing 33 are provided. When the interval in the arrangement direction of the bars 5 is to be 29 times or less of the width of the narrow bar, the mask print 33 is a value obtained by adding the lightness L *, the chromaticity a *, and the chromaticity b * vector, that is, (lightness L *). By configuring with + (chromaticity a *) + (chromaticity b *) of 74 or less, the mask print 33 is placed on the outermost side in the arrangement direction of the plurality of bars 5 displayed on the barcode symbol part 2. The bar displayed in the barcode symbol part 2 is not recognized as an edge of the mask print 33 if the two bars 5 are separated from the two bars 5 to the outside in the arrangement direction of the plurality of bars 5 more than 10 times the width of the narrow bar. Code 1 It will be able to accurately read.

DESCRIPTION OF SYMBOLS 1 Barcode 2 Barcode symbol part 3 Quiet zone 4 Background part 5 Bar 6 Barcode display medium 10 Wiring electrode board | substrate 11 Base board | substrate 12 Strip electrode 13 Wiring 14 Connection terminal 15 Blank electrode 20 Information display layer 21 Bulkhead 22 Liquid in partition 23 Charging Particles 24 Sealing Layer 30 Transparent Conductive Substrate 31 Transparent Substrate 32 Transparent Electrode 33 Mask Printing

Claims (1)

A first electrode layer composed of a plurality of strip-shaped electrodes disposed on one surface side of the base substrate, a second electrode layer formed on the transparent substrate and disposed opposite to the first electrode layer, and an information display layer sandwiched between the second electrode layer and the first electrode layer, wherein the information corresponding to the potential difference between the plurality of strip-shaped electrode and the second electrode layer Information expressed by the bar having the first color with the second color as a background by visually recognizing the first color and the second color by the display layer from the second electrode layer side. In a barcode display medium that displays barcodes arranged in a plurality in the width direction with a width and interval according to
A mask layer provided on a part of the transparent substrate so that the barcode can be visually recognized, and having a linear edge portion parallel to a plurality of bars to be displayed at an end on the side where the barcode is visually recognized. Have
The mask layer is from 2 bars to be aligned direction outermost of said plurality of bar arrangement direction outside of the 10 to 29-fold by the plurality of bars of a width narrowest bar width of the plurality of bars A bar code display medium, characterized in that the bar code display medium is provided at a distance and has a value of (lightness L *) + (chromaticity a *) + (chromaticity b *) of 74 or less.

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