JP2008176017A - Electrophoretic display medium and electrophoretic display device - Google Patents

Abstract

The present invention provides an electrophoretic display medium and an electrophoretic display device capable of obtaining good image quality by using two types of charged particles having different adhesive forces in an appropriate amount according to the respective adhesive forces. To do.
A display unit includes a plurality of first charged particles having a predetermined adhesion force and a plurality of second charged particles having an adhesion force smaller than that of the first charged particles. Similar to the case of charged particles, the frequency of aggregation of particles was reduced compared to the case of using particles having high adhesion as the second charged particles. In addition, since the amount of the second charged particles is included more than the amount covering the display substrate by forming one layer when moving to the display substrate side, the second charged particles having a small adhesion force are peeled off from the display substrate. Even in this case, the second charged particles cover the first charged particles adhering to the back substrate, and the color of the second charged particles is displayed on the display substrate side.
[Selection] Figure 4

Description

  The present invention relates to an electrophoretic display medium and an electrophoretic display device that display an image by moving charged particles using an electrophoretic phenomenon.

  Conventionally, an electrophoretic display medium that displays an image using an electrophoretic phenomenon is known. In this electrophoretic display medium, a sealed space is formed between a transparent display substrate and a back substrate disposed opposite to the display substrate at a predetermined interval. The display medium is formed by filling the sealed space with a dispersion medium in which colored charged particles are dispersed. For example, when the charged particles dispersed in the liquid dispersion medium are composed of black charged particles and white charged particles having a different charging polarity, black electric particles are generated by generating an electric field in the display unit. When the charged particles are moved to the display substrate side, black can be displayed on the display portion. Further, white can be displayed by generating a reverse electric field, and a desired image can be obtained by this combination.

  The charged particles used in such an electrophoretic display medium have an adhesive force between the charged particles and between the charged particles and the substrate. This adhesion force varies depending on the type of charged particles and the material of the substrate, and is determined by the liquid crosslinking force, van der Waals force, and the like. When the charged particles are aggregated by this adhesion force, a difference occurs in the moving speed when the charged particles are moved by generating an electric field between the aggregated particles and the non-aggregated particles. In addition, when the charged particles move to the display substrate side, the display substrate cannot be covered without a gap, so that when the user views the display unit from the display substrate side, the color of the other charged particle is visible. Accordingly, the contrast is lowered.

Therefore, an electrophoretic display medium using charged particles composed of mother particles and a plurality of fine particles attached to the surfaces of the mother particles has been proposed (see, for example, Patent Document 1). When such charged particles are used, the contact between the particles becomes almost a point contact, and the distance between the particles becomes longer than when charged particles to which fine particles are not attached are used. And since the van der Waals force acting between the particles becomes smaller as the distance between the particles becomes longer, the adhesion force generated between the particles decreases. Further, the contact between the particles becomes a point contact, so that the contact area is reduced and the adhesion force due to the liquid crosslinking force is reduced. With this configuration, a reduction in contrast due to aggregation of charged particles is prevented.
JP 2002-72256 A

  However, in the electrophoretic display medium described in Patent Document 1, not only agglomeration of charged particles but also an adhesion force between the charged particles and the substrate is reduced. Particles fall off. Then, in addition to the color of the charged particles to be displayed, the color of the other charged particles is visually recognized from the display substrate side, and there is a problem that the image quality is deteriorated.

  The present invention has been made to solve the above-mentioned problems, and by using two types of charged particles having different adhesion forces in an appropriate amount according to each adhesion force, good image quality can be obtained. It is an object to provide an electrophoretic display medium and an electrophoretic display device.

  In order to achieve the above object, an electrophoretic display medium according to claim 1 of the present invention includes a display panel having a transparent display substrate and a back substrate disposed to face the display substrate, the display substrate, and the display substrate. An electrophoretic display medium comprising: a display unit formed in a gap between back substrates; and charged particles contained in the display unit and moving in the display unit by the action of an electric field, wherein the charged particles are the display A plurality of first charged particles having a predetermined adhesion force with the substrate and a plurality of first charged particles that are charged to a polarity different from that of the first charged particles and have an adhesion force smaller than the adhesion force of the first charged particles The amount of the second charged particles is such that when the second charged particles move to the display substrate side, a plurality of the second charged particles form one layer. More than the amount that covers the display board To.

  Further, in the electrophoretic display medium according to claim 2 of the present invention, in addition to the configuration of the invention according to claim 1, the amount of the charged particles represented by the product of the particle diameter and the number of particles is: The second charged particles are more in number than the first charged particles.

  In addition to the configuration of the invention described in claim 1 or 2, the electrophoretic display medium according to claim 3 of the present invention is such that the amount of the first charged particles is such that the first charged particles are on the display substrate side. The plurality of first charged particles form an amount that covers the display substrate when moving to (1).

  In addition to the configuration of the invention according to any one of claims 1 to 3, the electrophoretic display medium according to claim 4 of the present invention is configured such that the amount of the second charged particles is the same as that of the second charged particles. When moving to the display substrate side, a plurality of the second charged particles are more than the amount forming two layers.

  The electrophoretic display medium according to claim 5 of the present invention has the structure of the invention according to any one of claims 1 to 4, and the adhesion of the first charged particles is the same as that of the second charged particles. It is characterized by being at least 2.5 times the adhesive force.

  An electrophoretic display device according to claim 6 of the present invention is the electrophoretic display medium according to any one of claims 1 to 5, a transparent first electrode provided on the display substrate, and the back substrate. And a voltage applying means for applying a voltage to the first electrode and the second electrode.

  According to the electrophoretic display medium of the first aspect of the present invention, the plurality of first charged particles having a predetermined adhesive force between the display substrate and the adhesive force smaller than the adhesive force of the first charged particles. Since a plurality of second charged particles are included in the display unit, the frequency of aggregation of particles is reduced as compared with the case where the adhesion force of the second charged particles is the same as the adhesion force of the first charged particles. Can do. Therefore, there is no variation in the moving speed of the charged particles due to the aggregation of the particles, and there is no gap between the charged particles attached to the display substrate due to the influence of the aggregated charged particles. can get. In addition, the amount of the second charged particles is larger than the amount that forms a single layer and covers the display substrate when moving to the display substrate side, so that the second charged particles are peeled off from the display substrate due to the small adhesive force. Even if it has occurred, the first charged particles adhering to the back substrate can be covered and the contrast is prevented from being lowered.

  In addition to the effect of the invention described in claim 1, the electrophoretic display medium described in claim 2 of the present invention has an amount of charged particles represented by the product of the particle diameter and the number of particles as follows. Since there are more second charged particles than one charged particle, when switching the display color, the time required for the second charged particles to get over the layer of the first charged particles having strong adhesive force and reach the opposite substrate is reduced. It can be shortened. That is, good image quality can be obtained without reducing the display switching speed.

  Further, in the electrophoretic display medium according to claim 3 of the present invention, in addition to the effect of the invention according to claim 1 or 2, since the first charged particles adhere to the substrate by the adhesion force even after the voltage application is stopped, If the amount of the first charged particles is an amount that forms one layer and covers the display substrate when moved to the display substrate side, sufficient image quality can be obtained. Furthermore, compared to the case where more first charged particles than this amount are used, the charged particles move smoothly in the display unit, and the display color can be switched in a short time.

  In addition to the effect of the invention according to any one of claims 1 to 3, the electrophoretic display medium according to claim 4 of the present invention, when the amount of the second charged particles moves to the display substrate side. Since it is more than the amount that forms two layers, even when the second charged particles are peeled off from the display substrate, the first charged particles adhering to the back substrate can be sufficiently covered, and good image quality is obtained. be able to.

  Further, in the electrophoretic display medium according to claim 5 of the present invention, in addition to the effect of the invention according to any one of claims 1 to 4, the adhesion of the first charged particles is the adhesion of the second charged particles. Therefore, the first charged particles are less likely to be peeled off from the display substrate, that is, the rate of change in luminance when displaying the color of the first charged particles is small, and thus good image storage stability. Is obtained.

  According to a sixth aspect of the present invention, in addition to the electrophoretic display medium according to any one of the first to fifth aspects, a transparent first electrode is provided on the display substrate, and a second electrode is provided on the rear substrate. Since the electrode further includes voltage applying means for applying a voltage to the first electrode and the second electrode, the same effects as the invention according to any one of claims 1 to 4 can be achieved.

  Hereinafter, an electrophoretic display device 1 embodying an electrophoretic display device according to the present invention will be described with reference to the drawings. FIG. 1 is a plan view of the electrophoretic display device 1, and FIG. 2 is a cross-sectional view of the display panel 2 shown in FIG. 2 is the upper side of the display panel 2, and the lower side of FIG. The display panel 2 of the present embodiment is mounted on, for example, a portable electronic device and can display various images by being driven and controlled by the control device 3.

  First, an outline of the configuration of the electrophoretic display device 1 of the present embodiment will be described. As shown in FIG. 1, the electrophoretic display device 1 includes a display panel 2 and a control device 3. The display panel 2 and the control device 3 are electrically connected. The display panel 2 is formed in a rectangular shape in plan view. Next, as shown in FIG. 2, the display panel 2 includes a display substrate 10 provided substantially horizontally on the upper side, and a rear substrate disposed on the lower side of the display substrate 10 so as to be opposed substantially horizontally via a spacer 31. 20. In the gap between the display substrate 10 and the back substrate 20, a plurality of display units 30 separated by the partition walls 32 are formed. Hereinafter, the detailed structure of each component will be described in order.

  First, the structure of the display substrate 10 will be described. As shown in FIG. 2, the display substrate 10 is formed of a transparent member and is provided with a display layer 11 serving as a display surface, and a transparent common electrode provided below the display layer 11 and generating an electric field in the display unit 30. 12 and a protective layer 13 provided below the common electrode 12 and protecting the common electrode 12. The display layer 11 is formed of a material having high transparency and high insulation, and for example, polyethylene naphthalate, polyethersulfone, polyimide, polyethylene terephthalate, glass or the like is used. On the other hand, the common electrode 12 is formed of a material having high transparency and can be used as an electrode. For example, indium tin oxide which is a metal oxide, tin oxide doped with fluorine, zinc oxide doped with indium, and the like Is used. In this embodiment, the display layer 11 is a transparent glass substrate, the common electrode 12 is a transparent electrode formed of indium tin oxide, and the protective layer 13 is a resin made of flexible polyvinyl alcohol. It is a film. The common electrode 12 in the present embodiment corresponds to the “first electrode” of the present invention.

  Further, as shown in FIGS. 1 and 2, the upper surface of the display substrate 10 (the surface that does not face the rear substrate 20) is hidden in a plan view so that the peripheral portion of the display unit 30 cannot be visually recognized by the user. A mask portion 35 is provided. The mask part 35 is a plate-shaped member having a square shape in plan view provided with a constant width along the four sides of the display substrate 10 and provided with a through hole so that the user can visually recognize the display part 30. The mask portion 35 may be formed by adhering a colored synthetic resin such as polyethylene terephthalate or by forming an ink layer printed on the surface of the display layer 11. As a result, when the display panel 2 is viewed from above, the display area including the plurality of display units 30 can be viewed from the through holes provided in the mask unit 35.

  Next, the structure of the back substrate 20 will be described. As shown in FIG. 2, the back substrate 20 is provided for each display unit 30 on the upper surface of the housing support layer 21 that supports the display panel 2 and on the upper surface of the housing support layer 21. And a protective layer 23 provided on the upper surface of the pixel electrode 22. Although not shown, a TFT (Thin Film Transistor) is incorporated in the housing support layer 21, and the TFT is connected to each divided pixel electrode 22 to apply a voltage to each pixel electrode 22. Control (on / off). Moreover, the material which has high insulation is used for the material of the housing support layer 21, and for example, an inorganic material such as glass or an insulating metal film, or an organic material such as polyethylene terephthalate is used. Each layer forming the back substrate 20 may be transparent or colored, unlike the display substrate 10. In the present embodiment, the housing support layer 21 is a glass substrate, the pixel electrode 22 is an electrode formed of indium tin oxide, and the protective layer 23 is a resin film made of flexible polyvinyl alcohol. . The pixel electrode 22 corresponds to the “second electrode” of the present invention.

  Next, the structure of the display unit 30 will be described. As shown in FIG. 2, a spacer 31 is installed between the display substrate 10 and the back substrate 20. The spacer 31 is a flexible member configured as a plate member having a square shape in plan view with a through hole provided in the center, and a sealed space between the display substrate 10, the back substrate 20, and the spacer 31. Is formed. The sealed space is further equally divided into a plurality of display units 30 by partition walls 32, and the pixel electrodes 22 described above are divided corresponding to the display units 30. Here, the pixels of the electrophoretic display device 1 are formed for each divided pixel electrode 22, and a plurality of pixels may be included in one display unit 30, or conversely, a plurality of pixels are included in one pixel. The display unit 30 may be included. Further, the spacer 31 and the partition wall 32 may be integrally formed. In the present embodiment, both the spacer 31 and the partition wall 32 are formed of an epoxy-based photocurable resin.

  In the display unit 30 formed by the above structure, the dispersion medium 40 including the black charged particles 50 and the white charged particles 60 is enclosed, and the black charged particles 50 are moved to the display substrate 10 side. Black is displayed on the display unit 301, and white is displayed on the display unit 302 in which the white charged particles 60 are moved to the display substrate 10 side. In the present embodiment, black charged particles 50 and white charged particles 60 having different adhesion forces are used, and an appropriate amount of charged particles according to the adhesion force of each charged particle is dispersed in the dispersion medium 40 to improve the image quality. The details are described later.

  Next, the electrical configuration of the electrophoretic display device 1 will be described with reference to FIG. FIG. 3 is a block diagram showing an electrical configuration of the electrophoretic display device 1. The control device 3 of the electrophoretic display device 1 includes a control unit 90 that controls the display mode of the image by driving the display panel 2, a power source 91 that supplies power to the electrophoretic display device 1, and a display on the display panel 2. Display data memory 93 for storing display data indicating an image to be displayed, a timer 94 for counting the voltage application time to each electrode, an interface 99 for exchanging data with the outside, the common electrode 12 and each pixel electrode 22 And a driver 95 for controlling the applied voltage. The control unit 90 is provided with a CPU, ROM, RAM, etc., not shown.

  With this configuration, the control unit 90 sends a signal for controlling the image forming operation to the driver 95 based on a video signal and a synchronization signal input from the outside and various data stored in the display data memory 93. Send. Then, the driver 95 applies a voltage to the common electrode 12 and each pixel electrode 22 at predetermined timings, and causes the black charged particles 50 and the white charged particles 60 charged to different polarities to move in the vertical direction (vertical direction in FIG. 2). Move. Then, the color of the charged particles that have moved to the display substrate 10 side is displayed on the display substrate 10. In the present embodiment, the electrode on the back substrate 20 side is divided for each pixel as the pixel electrode 22, but instead the electrode on the display substrate 10 side may be divided for each pixel. That is, a plurality of pixels can be provided in the display region by dividing at least one of the two opposing electrodes into a plurality of sections.

  Next, the adhesion force of charged particles dispersed in the liquid dispersion medium will be described. When the charged particles are dispersed in the dispersion medium 40, an adhesive force is generated between the charged particles and the substrate that are in contact with each other and between the charged particles that are in contact with each other. This adhesion force is mainly determined by the van der Waals force and the liquid crosslinking force. Van der Waals force is an attractive force acting between molecules, and the larger the particle size of the charged particles, the larger the van der Waals force generated. Furthermore, the van der Waals force increases as the distance between the charged particles and the substrate or the distance between the charged particles decreases. The liquid cross-linking force is a force generated by cross-linking between the charged particles and the substrate or between the charged particles and the charged particles by the surface adsorbed liquid, and the magnitude thereof is the surface tension of the liquid. , And the affinity of the particle or substrate. Specifically, the liquid crosslinking force increases as the surface tension of the liquid used as the dispersion medium 40 increases, and if the affinity between the charged particles and the substrate is the same (both hydrophilic or both hydrophobic). The liquid cross-linking force is greater than when the affinity is different. Further, the liquid crosslinking force decreases as the contact area between the charged particles and the substrate or between the charged particles decreases.

  Therefore, in order to increase the adhesion force acting between the charged particles and the substrate, a method of increasing the particle diameter of the charged particles, a method of using a liquid having a higher surface tension as the dispersion medium 40, the affinity of the charged particles, There is a method of selecting and using a material so that the affinity of the substrate is the same. On the other hand, in order to reduce the adhesive force acting between the charged particles and the substrate, a method of reducing the particle diameter of the charged particles, a method of using a liquid having a lower surface tension as the dispersion medium 40, and the affinity of the charged particles A method of selecting and using materials so that the affinity of the substrate and the substrate is different, and further using as the charged particles a particle in which a plurality of fine particles having a particle diameter smaller than the particle diameter of the mother particle are attached to the surface of the mother particle Thus, there is a method in which the distance between the center of the charged particles and the substrate is increased by the amount of the fine particles, and the van der Waals force is reduced.

  Even when no voltage is applied between the common electrode 12 and the pixel electrode 22 and no Coulomb force is applied to the charged particles, if the adhesion force of the charged particles dispersed in the dispersion medium 40 is increased, Particles adhere to the surface of the substrate due to adhesion. Therefore, the image quality does not deteriorate significantly even if time passes as it is. However, as the adhesion force of the charged particles is increased, the charged particles are aggregated. When the charged particles are aggregated, the moving distance and moving speed when an electric field is generated between the charged particles and the non-aggregated charged particles vary, and when the charged particles move toward the display substrate 10, the display substrate 10. It is difficult to cover without any gap. Therefore, when the user looks at the display unit from the display substrate 10 side, the color of the charged particles located on the back substrate 20 side can be seen, so the contrast is lowered.

  On the other hand, as the adhesive force of the charged particles dispersed in the dispersion medium 40 is reduced, the charged particles are less likely to aggregate and the charged particles cover the display substrate 10 without any gaps. Good contrast is obtained when moving to. However, since the adhesion force generated between the charged particles and the substrate is also reduced, when the voltage application is stopped, the charged particles attached to the substrate are peeled off over time. As a result, different types of charged particles are mixed, resulting in a reduction in image quality.

  In the present invention, paying attention to the adhesion force of the charged particles described above, two kinds of charged particles are selected so that the adhesion force of the black charged particles 50 and the adhesion force of the white charged particles 60 are different, and each adhesion force is selected. By setting the amount of black charged particles 50 and white charged particles 60 to an appropriate amount in accordance with the above, it is possible to obtain an image quality that is better than when using a plurality of types of charged particles having the same adhesion force. The electrophoretic display device 1 is realized. In addition, by making the adhesion of the white charged particles 60 in the present embodiment 2.5 times or more of the adhesion of the black charged particles 50, the white charged particles 60 are less likely to be peeled from the substrate, and the luminance change rate is reduced. This was confirmed by Example 5 described later.

  Next, a method for measuring the amount of charged particles used in the present embodiment will be described. In order to measure the amount of charged particles, both the number of charged particles and the average particle diameter of the charged particles must be considered. Therefore, in this embodiment, when comparing the amount of a plurality of charged particles, the product of the average particle diameter and the number of charged particles is calculated, and the amount of charged particles is compared by comparing this value. Further, when measuring the amount of charged particles dispersed in the dispersion medium 40, the minimum necessary for the charged particles to form a single layer and cover the portion of the display substrate 10 facing the plurality of display units 30. The amount of the charged particles was measured based on this amount as the “amount covering the display substrate 10 with one layer”. Specifically, the average particle diameter of the charged particles is measured using a Microtrac (registered trademark) particle size distribution measuring device (manufactured by Nikkiso Co., Ltd.), and the portion of the display substrate 10 facing one display unit 30 is measured. The length of the four sides and the number of display units 30 are measured, and using these three values, the number of charged particles to be dispersed in the dispersion medium 40 is determined so as to cover the display substrate 10 with one layer. The amount by which the substrate 10 is covered with one layer can be measured. In the following description, “amount of display substrate 10 covered by one layer” is expressed as “one layer”, and 1.5 times the amount of one layer is “1.5 layers” on the basis of this amount. The amount of particles is expressed as “two layers” for a double amount for one layer.

  Next, the dispersion medium 40, the black charged particles 50, and the white charged particles 60 used in the electrophoretic display device 1 of the present embodiment will be described. As the liquid dispersion medium, alcohols, hydrocarbons, silicone oils or the like that can exhibit high insulation properties can be used. In this embodiment, a small amount of alcohol is added to the hydrocarbon-based insulating solvent. Further, as the charged particles, a material that can be charged in the dispersion medium 40 is used, and a pigment or dye made of an organic compound or an inorganic compound, or a pigment or dye wrapped with a synthetic resin can be used. Specifically, crosslinked PMMA (polymethyl methacrylate), PC (polycarbonate), HDPE (high density polyethylene), PP (polypropylene), ABS (acrylonitrile butadiene styrene), PET (polyethylene terephthalate), POM (polyacetal), etc. Can be used. In the present embodiment, the black charged particles 50 are obtained by attaching silica fine particles to the surface of carbon black-containing PMMA resin particles using a hybridization system (registered trademark) (manufactured by Nara Machinery Co., Ltd.). In addition, titanium oxide-containing PMMA resin particles were used as white charged particles 60. In this case, the adhesion force of the black charged particles 50 is smaller than the adhesion force of the white charged particles 60. The white charged particles 60 correspond to “first charged particles” of the present invention, and the black charged particles 50 correspond to “second charged particles”.

  Next, referring to FIG. 4, in the electrophoretic display device 1 using two types of charged particles 50 and 60, it is appropriate when the adhesion force of the black charged particles 50 and the adhesion force of the white charged particles 60 are different. The amount of each charged particle will be described. FIG. 4 is a diagram showing an example of the state of the black charged particles 50 and the white charged particles 60 when a predetermined time has elapsed after the voltage application is stopped in the display panel 2 shown in FIG.

  First, the amount of the black charged particles 50 will be described. Since the adhesion force of the black charged particles 50 is smaller than the adhesion force of the white charged particles 60, the particles are less likely to aggregate than when the adhesion force of the black charged particles 50 is as large as the adhesion force of the white charged particles 60. . On the other hand, since the black charged particles 50 have a small adhesive force on the surface of the display substrate 10, the black charged particles 50 are peeled off from the display substrate 10 over time. Therefore, the black charged particles 50 were dispersed in the dispersion medium 40 more than the amount covering the display substrate 10 with one layer. As a result, as shown in FIG. 4, even when the voltage application is stopped and time elapses and the black charged particles 50 in the display unit 301 displaying black color are peeled off from the display substrate 10, the peeled black color is removed. Since the charged particles 50 cover the white charged particles 60 adhering to the surface of the back substrate 20, black is visually recognized from the display substrate 10 side. In addition, if the white charged particles 60 having a small adhesive force are used as in the case of the black charged particles 50, both of the two types of charged particles are peeled off from the substrate and the image storage stability is deteriorated. Since the particles 60 have a strong adhesive force to the display substrate 10, the white image storage stability is also good. Therefore, it is possible to maintain image storability while reducing the frequency of aggregation of charged particles compared to the case where particles having the same adhesion as the white charged particles 60 are used as the black charged particles 50. This could be confirmed by Example 1 described later. Further, it can be confirmed from Example 2 described later that the amount of the black charged particles 50 is desirably dispersed more than the amount (two layers) covering the display substrate 10 by forming two layers. It was.

  Further, when switching the displayed color, the black charged particles 50 must reach the opposite substrate by overcoming the layer of white charged particles 60 that are strongly adhered to the substrate. As the amount of the white charged particles 60 increases, the time until the black charged particles 50 get over the layer of the white charged particles 60 becomes longer, and the display color switching speed becomes slower. Therefore, the amount of the charged particles represented by the product of the average particle diameter and the number of particles was dispersed more in the black charged particles 50 than in the white charged particles 60. It was confirmed by Example 3 described later that this configuration enables quick display color switching.

  Next, the amount of the white charged particles 60 will be described. As shown in FIG. 4, the adhesion force of the white charged particles 60 is larger than the adhesion force of the black charged particles 50, so that the application of voltage is stopped and time passes, and the black charged particles 50 are peeled off from the back substrate 20. Even when moving inside the display unit 302, the white charged particles 60 continue to adhere to the display substrate 10. As described above, as the amount of the white charged particles 60 decreases, the black charged particles 50 quickly reach the opposite substrate when switching the display color. Therefore, the white charged particles 60 were dispersed in the dispersion medium 40 by an amount (one layer) covering the display substrate 10 with one layer. As a result, it was confirmed by Example 3 and Example 4 described later that it is possible to quickly switch the display color while maintaining the white image quality.

The electrophoretic display device 1 described above was subjected to the tests shown in Examples 1 to 5 in order to confirm the effect of the present invention. Examples 1 to 5 will be described below. In the luminance evaluation tests performed in Examples 1 to 5, the luminance (cd / m ² ) of the specific display unit 30 from the display substrate 10 side using a color luminance meter (BM-7: manufactured by Topcon Corporation). ) Was measured. Furthermore, in Examples 2 to 4, the luminance value of the display unit 30 displaying white is divided by the luminance value of the display unit 30 displaying black, so that the luminance of black is “1”. In this case, the brightness of white is calculated, and this value is used as the “contrast ratio” in the evaluation criteria of the example. As the contrast ratio increases, the difference between the luminance of white and the luminance of black increases, and image recognition becomes easier. In Examples 1 to 5, the distance between the display substrate 10 and the back substrate 20 was 50 μm, and the potential difference between the common electrode 12 and the pixel electrode 22 during voltage application was 30V. The material used is the same as the material used in the electrophoretic display device 1 described above.

[Example 1]
First, an evaluation test was performed on the relationship between the amount of dispersion of the black charged particles 50, which are particles having a smaller adhesion force, and the rate of change in luminance that changes over time. In this evaluation test, display liquid A in which black charged particles 50 are dispersed for two layers and white charged particles 60 are dispersed for one layer, and two types of charged particles 50 and 60 are dispersed for one layer as a comparison target. preparing a display liquid B was, and the measured luminance (initial luminance) L ₁ at the time of each voltage applied to the cases of white display and black display, the luminance L ₂ at the time lapse of one minute after voltage application is stopped Thus, the luminance change rate C was calculated. The value of the luminance change rate C (%) is obtained by the following equation.
C = | L ₁ −L ₂ | / L ₁ × 100

As shown in Table 1, as a result of this evaluation test, in the display liquid A in which two layers of black charged particles 50 are dispersed, the white display luminance (cd / m ² ) is “87.3” when a voltage is applied, When 1 minute passed, it was “87.4” and the luminance change rate was 0.1%. The luminance of black display was “16.4” when a voltage was applied, and “16.5” after 1 minute, and the luminance change rate was 0.6%. The change in luminance at this time was a minute change that could not be confirmed with the naked eye. On the other hand, in the display liquid B in which the black charged particles 50 for one layer are dispersed, the luminance of white display is “91.4” when a voltage is applied and “90.3” when one minute has elapsed, and the luminance change rate is 1. It was 2%. The luminance of the black display is “16.8” when a voltage is applied and “18.5” when one minute has elapsed, the luminance change rate is 10.1%, and the change in the luminance of the black display can be easily changed with the naked eye. It could be confirmed. In this result, although there is no significant difference in the luminance change rate of white display, the luminance change rate (0.6%) of black display when the amount of the black charged particles 50 to be dispersed is two layers is one layer. This is much smaller than the luminance change rate (10.1%) of the black display. From this result, it was found that the storage quality of the image quality of black display was greatly improved by setting the amount of the black charged particles 50 to be dispersed to two layers as compared with the case of using one layer. This is considered to be because, even when the black charged particles 50 are peeled off from the display substrate 10, the peeled black charged particles 50 cover the white charged particles 60 adhering to the surface of the back substrate 20.

[Example 2]
Next, an evaluation test was performed on the relationship between the amount of the black charged particles 50, which are particles with weaker adhesion, and the contrast ratio. In this evaluation test, the plate surface on the display substrate 10 side of the back substrate 20 is colored to the same white color as the white charged particles 60, and the amount of black charged particles 50 dispersed in the dispersion medium 40 is changed to obtain black luminance and white. The contrast ratio with the luminance (when the black charged particles 50 are not dispersed) was calculated. Specifically, the black charged particles 50 are not dispersed in the display liquid C as a comparison target. The display liquid D is 0.5 layer, the display liquid E is 1 layer, the display liquid F is 1. Black charged particles 50 for 5 layers, 2 layers for display liquid G, 2.5 layers for display liquid H, and 4.5 layers for display liquid I are dispersed. And using each display liquid, the brightness | luminance at the time of black display was measured at the time of voltage application, and the contrast ratio when black brightness | luminance was set to "1" was computed.

  As shown in Table 2, as a result of this evaluation test, as the amount of the black charged particles 50 dispersed in the dispersion medium 40 is increased, the difference in luminance between the white display and the black display is increased and the contrast ratio is improved. I understood. In general, the contrast ratio between white and black in newspaper is 6: 1. If this value is a reference for sufficient image quality, the display liquid G, the display liquid H, and the display liquid I are the reference. The result of satisfying came out. Therefore, the amount of the black charged particles 50 to be dispersed is more preferably two or more layers.

[Example 3]
Next, an evaluation test was performed on the relationship between the dispersion ratio of the amount of the black charged particles 50 and the amount of the white charged particles 60 and the display color switching speed. In this evaluation test, the amount of black charged particles 50 to be dispersed was fixed to one layer, and only the amount of white charged particles 60 was changed to measure the switching speed. Specifically, the display liquid J has one layer of black charged particles 50 and one layer of white charged particles 60, and the display liquid K has one layer of black charged particles 50 and one layer of white charged particles 60. In the display liquid L, black charged particles 50 are dispersed in one layer and white charged particles 60 are dispersed in 0.8 layers. Then, when the display color was switched from black to white, the time until the luminance changed by 90% was measured for each display liquid.

  As shown in Table 3, as a result of this evaluation test, in the display liquid J in which the amount of dispersed white charged particles 60 is 1.2 layers, it took 100 msec until the display color was switched. Each time the amount of the particles 60 was reduced, the switching time was shortened to 50 msec for the display liquid K and 30 msec for the display liquid L. As a result, when the amount of the white charged particles 60 is smaller than the amount of the black charged particles 50, the switching speed of the display color increases and the switching time becomes shorter than when the amount of the black charged particles 50 is larger than the amount of the black charged particles 50. I understood. It was also found that the switching time is shorter when the amount of the white charged particles 60 having a strong adhesive force is small.

[Example 4]
Next, an evaluation test was performed on the relationship between the amount of the white charged particles 60 that are particles having the stronger adhesion and the contrast ratio. In this evaluation test, the plate surface on the display substrate 10 side of the back substrate 20 is colored the same black as the black charged particles 50, and the amount of white charged particles 60 dispersed in the dispersion medium 40 is changed to change black (white charged particles). The contrast ratio between the luminance of 60 and the luminance of white was calculated. In detail, the white liquid particles 60 are not dispersed in the display liquid M as a comparison target. The display liquid N is 0.5 layer, the display liquid O is 1 layer, and the display liquid P is 1 layer. Five layers of white charged particles 60 are dispersed. And using each display liquid, the brightness | luminance at the time of white display was measured at the time of voltage application, and the contrast ratio when black brightness | luminance was set to "1" was computed.

  As shown in Table 4, as a result of this evaluation test, the contrast ratio of the display liquid O for one layer was improved compared to the display liquid N for which the amount of white charged particles 60 was 0.5 layers. The contrast ratio of the display liquid P in which the amount of the white charged particles 60 was further increased to 1.5 layers was the same as the contrast ratio of the display liquid O. From this result, it was found that, for the white charged particles 60 having strong adhesion, sufficient contrast can be obtained by dispersing one layer in the dispersion medium 40. Furthermore, from the results of Example 3 described above, it has been found that the display color switching time is shortened when the amount of the white charged particles 60 having strong adhesion is reduced. Therefore, the amount of the white charged particles 60 to be dispersed is more preferably one layer.

[Example 5]
Next, an evaluation test was performed on the relationship between the adhesion force of the black charged particles 50 and the white charged particles 60 and the luminance change rate that changes with the passage of time. In this evaluation test, first, the adhesion force of the white charged particles 60 is 2.5 times as large as the display solution Q which is 1.3 times the adhesion force of the black charged particles 50 and 1.7 times. Five display liquids, display liquid S, display liquid T which is 3.3 times, and display liquid U which is 11.0 times, were prepared. Then, the luminance change rate at the lapse of 1 minute after the voltage application was stopped in the case of white display was calculated by the same method as in Example 1 described above. The amount of the black charged particles 50 dispersed in each display liquid is all for two layers, and the amount of the white charged particles 60 is all for one layer. Moreover, the adhesive force of each charged particle was measured by the following method. First, charged particles are dispersed on a glass substrate, and the area of the charged particles is obtained by image analysis. Thereafter, the glass substrate is placed in a centrifuge and the area of charged particles remaining on the glass substrate after being rotated for a predetermined time is determined. This operation is performed a plurality of times while changing only the number of rotations per minute (rpm), and from the rotation speed when the area of the charged particles after the rotation is 50% of the area before the rotation, Obtain the centrifugal force applied to the charged particles. Using this value as the average adhesion force of the charged particles, the ratio of the adhesion force of the black charged particles 50 and the white charged particles 60 was measured.

  As shown in Table 5, as a result of this evaluation test, the luminance change rate is increased as the adhesion force of the white charged particles 60 is 1.3 times, 1.7 times, and 2.5 times the adhesion force of the black charged particles 50. It has been confirmed that the luminance change rate does not change much when 3.3 and 11.0 times are further reduced. Here, it is known that a measurement error of about 5% occurs when the luminance change rate is measured using the color luminance meter used in this embodiment. On the basis of this, considering that the case where the luminance change rate is within 5% is a good result, in order to obtain good image storability, the adhesion of the white charged particles 60 is applied to the black charged particles 50. It can be said that it is desirable to set it to 2.5 times or more of the wearing force.

  It should be noted that the present invention is not limited to the embodiment described in detail above, and various modifications can be made without departing from the scope of the present invention. For example, in the present embodiment, the particles with stronger adhesion are white and the particles with weak adhesion are black, but the color of the charged particles is not limited to this. That is, the present invention can be realized if the color and adhesion force are different between the two types of charged particles. In the present embodiment, the display panel 2 includes the common electrode 12 and the pixel electrode 22, and the control device 3 that is a voltage application unit is formed integrally with the display panel 2, but the two electrodes and the voltage application unit are provided. The provided voltage applying device and the electrophoretic display medium that does not have a means for applying a voltage by itself may be formed separately. In this case, the electrophoretic display medium is arranged and driven between the two electrodes of the voltage application device.

  The electrophoretic display medium and the electrophoretic display device according to the present invention are applied to various electronic devices including a display unit. For example, electronic paper etc. are mentioned. The electronic paper is provided with a main body and a display unit made of a rewritable sheet that is as thin as paper and has a display image quality that is close to that of paper, and the display unit includes the above-described electrophoretic display device.

  Moreover, you may use for the display part of the apparatus integrated with the operation part like a mobile computer. In such a case, a desired image is displayed on the display unit based on the signal of the content operated from the operation unit. In addition, it can be applied as a display unit provided in an electronic device such as a mobile phone, an electronic book, a television, and a calculator.

1 is a plan view of an electrophoretic display device 1. FIG. It is an AA arrow direction sectional view of the display panel 2 shown in FIG. 2 is a block diagram showing an electrical configuration of the electrophoretic display device 1. FIG. FIG. 3 is a diagram showing an example of the state of black charged particles 50 and white charged particles 60 when a predetermined time has elapsed after voltage application is stopped in the display panel 2 shown in FIG. 2.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electrophoretic display device 2 Display panel 3 Control device 10 Display substrate 11 Display layer 12 Common electrode 20 Back substrate 21 Case support layer 22 Pixel electrode 30 Display unit 40 Dispersion medium 50 Black charged particle 60 White charged particle

Claims (6)

A display panel having a transparent display substrate and a back substrate disposed opposite to the display substrate;
A display unit formed in a gap between the display substrate and the back substrate;
An electrophoretic display medium comprising charged particles contained in the display unit and moving in the display unit by the action of an electric field,
The charged particles are
A plurality of first charged particles having a predetermined adhesive force with the display substrate;
The first charged particles are charged to a different polarity, and consist of a plurality of second charged particles having an adhesion force smaller than the adhesion force of the first charged particles,
The amount of the second charged particles is larger than the amount of the plurality of second charged particles forming one layer and covering the display substrate when the second charged particles move to the display substrate side. An electrophoretic display medium characterized by the above.   2. The electrophoretic display according to claim 1, wherein the amount of the charged particles expressed by the product of the particle diameter and the number of particles is larger in the second charged particles than in the first charged particles. Medium.   The amount of the first charged particles is such that when the first charged particles move to the display substrate side, the plurality of first charged particles form one layer and cover the display substrate. The electrophoretic display medium according to claim 1 or 2, characterized in that:   The amount of the second charged particles is larger than an amount by which the plurality of second charged particles form two layers when the second charged particles move to the display substrate side. The electrophoretic display medium according to any one of 1 to 3.   The electrophoretic display medium according to claim 1, wherein the adhesion of the first charged particles is 2.5 times or more of the adhesion of the second charged particles. An electrophoretic display medium according to any one of claims 1 to 5,
A transparent first electrode provided on the display substrate;
A second electrode provided on the back substrate;
An electrophoretic display device comprising: voltage applying means for applying a voltage to the first electrode and the second electrode.

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