JP2004347719A - Picture display medium and picture forming device using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a picture display medium using display particles with various colors and electrostatic charge characteristics, which is inexpensive, is capable of rewriting pictures and is left standing for a long period of time. <P>SOLUTION: The picture display medium has an upper electrode 3 and a lower electrode 5, of which at least one is transparent and conductive, respectively on substrates 1, 2. A plurality of display particles 8, 9 with various electrostatic charge characteristics and colors are enclosed in between an insulating layer 4 on the upper electrode and an insulating layer 6 on the lower electrode. An electromagnetic induction coil 12 connected to the upper electrode and the lower electrode is tightly sealed with an electrical insulating protective body 13 and receives a magnetic flux from an external electromagnetic induction coil 15. When a switch S is turned on, an electric field is formed between the upper electrode and the lower electrode and the display particles are transferred by the electric field. A polarity and intensity of the electric field formed between the electrodes are varied by adjusting variation of the supplied magnetic flux. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image display medium using an electrostatic recording method using dielectric particles, and an image forming apparatus using the image display medium, and more specifically, can apply a voltage generated by electromagnetic induction, The present invention relates to a monochrome and color image display medium that can be repeatedly rewritten by exposure and an image forming apparatus thereof.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, characters and images are created as digital data by a computer, a digital camera, or the like, and the confirmation is performed by displaying on a CRT or a liquid crystal display. Further, when digital data is distributed or stored in the form of a document or the like, a so-called hard copy in which the digital data is recorded on a paper medium using a printer is widely used. When digital data is displayed on a display, a CRT, a liquid crystal panel, a plasma display panel, an organic EL, and the like are used. It has become a central player as an image display medium.
[0003]
These have the feature that digital data can be displayed instantaneously and the next screen can be displayed instantaneously. However, it is difficult to carry around the display device, and there are many disadvantages such as tired eyes in a long-time operation, or no display when the power is turned off. In addition, the hard copy is easier to read the sentence than the display, is less tired, and can be read in a free posture. Furthermore, it has a feature that it is lightweight and can be freely carried.
[0004]
However, in the case of recording using a hard copy, the above advantages are provided, but after being used, they are discarded and recycled, but this requires a lot of labor and cost, There is a problem in saving resources.
[0005]
Therefore, a rewritable paper-like display medium that has the advantages of both a display and a hard copy can record images, and after use, erases unnecessary display images and reuses them over and over. It is possible. For this reason, attention has been paid in recent years because resources can be saved as a display medium from this viewpoint. As a technique having such features, a transparent white turbid type rewritable marking medium or a color erasable type rewritable marking medium using a leuco dye is in practical use as a rewritable card.
[0006]
In addition, white particles and an insulating fluid are microencapsulated, and an image is displayed by rotating an electrophoretic display medium that displays an image by electrophoresis or minute spherical particles colored into two colors embedded in a resin thin film. Twisted ball type display media, and image display media for displaying images by moving conductive particles by charge injection using conductive particles and insulating particles having different colors have been studied (for example, patents). Reference 1).
[0007]
[Patent Document 1]
JP 2000-322997 A
[0008]
[Problems to be solved by the invention]
However, these particle moving type image display media are based on a display principle of moving display particles by an applied electric field and performing image display, and therefore include two substrate electrodes enclosing the display particles. In addition, a voltage for forming an electric field is applied from the outside, and an electrode terminal connected to the substrate electrode is required.
[0009]
Therefore, after the writing to the image display medium is completed, the voltage supply terminal of the power supply device is disconnected from the electrode terminal, so that the electrode terminal is exposed to the air. If the display particles are left for a long time in this state, the display particles may lose charge due to spontaneous discharge from the electrode terminals to the outside. In particular, in the case of a dry-type image display medium in which display particles are dispersed in a gas as an insulating fluid, there is a problem that it is difficult to rewrite an image.
[0010]
In the case of this dry type image display medium, the charge of the display particles, which is dielectric, is performed by frictional charging between the display particles. Therefore, triboelectric charging occurs in the manufacturing stage of the display medium, and at this stage, the display particles are charged. For this reason, rewriting on the image display medium utilizes the first charge due to frictional charging, and subsequent rewriting is performed with a relatively low voltage from the outside.
[0011]
However, once the charge obtained by the triboelectric charge is lost from the display particles by spontaneous discharge, the next time the image display medium is rewritten, the display particles will be charged unless a very high voltage is applied to the substrate electrode. I can't let it. Alternatively, a high-frequency AC electric field must be generated between the substrate electrodes to vibrate the display particles, and then the display particles must be subjected to triboelectric charging. As described above, once the charge due to the triboelectric charge disappears, it becomes difficult to reuse the charge unless a specially prepared power supply device is provided.
[0012]
Further, even in the case of a particle migration type image display medium, a phenomenon occurs in which a display image becomes unclear as a result of disappearance of induced charges in the insulating film. Further, when the electrode terminals are exposed, there is a risk that the display image is unnecessarily rewritten due to, for example, the influence of static electricity from the outside.
[0013]
By the way, in order to prevent the disappearance of such charges or the supply of unnecessary charges from the outside, it is conceivable to separately prepare a member for sealing the electrode terminals, but for a paper-like image display medium, In addition, not only the characteristics of the medium are lost, but also the sealing operation performed every time the image is rewritten becomes complicated and troublesome. Further, the cost is increased because the member must be prepared.
[0014]
Therefore, an object of the present invention is to provide a different color and charging characteristic that enables good image contrast, good lightness, color display, inexpensive image rewriting, no spontaneous discharge, and long-term storage. It is an object of the present invention to provide an image display medium using display particles having the same, and an image forming apparatus therefor.
[0015]
[Means for Solving the Problems]
In order to solve the above problems, in the present invention, at least one of the first and second electrodes has a transparent conductive property, and a plurality of display particles having different charging characteristics and colors are formed on an insulating layer on the first electrode. In an image display medium sealed between the first electrode and the second electrode and moved by an electric field formed between the first electrode and the second electrode, the electromagnetic induction coil includes a first electrode and a second electrode. And the first electrode and the second electrode are hermetically sealed by an electric insulator, and a magnetic flux is supplied to the electromagnetic induction coil, whereby the electric field is formed between the first electrode and the second electrode. I decided to do it. Further, the display particles are dispersed in an insulating fluid sealed between the opposing insulating layers.
[0016]
The magnetic flux is supplied from another electromagnetic induction coil adjacent to the electromagnetic induction coil, and the electromagnetic induction coil is connected to a first electrode or a second electrode via a switch, and the magnetic flux is supplied to the electromagnetic induction coil. The switch is turned on when the power is supplied to the coil.
[0017]
The magnetic flux supplied from the other electromagnetic induction coil has a steep change and a gradual change in time, and the polarity of the electric field is determined by the order of the steep change and the gradual change in the magnetic flux. Alternatively, a rectifier circuit is connected between the electromagnetic induction coil and the first electrode or the second electrode.
[0018]
Further, the electromagnetic induction coil is formed on the inner surface of the electrically insulating body at a peripheral portion of the first electrode and the second electrode.
[0019]
Further, in the image display medium, a photoconductive layer is formed between the transparent conductive first electrode or the second electrode and the insulating layer, and the photoconductive layer is formed on the photoconductive layer via the first electrode or the second electrode. It is assumed that writing light is applied, and a color filter layer is formed on the surface of the first electrode or the second electrode on the side facing the photoconductive layer.
[0020]
Further, according to the present invention, in the above-described image forming apparatus for an image display medium, the first electrode and the second electrode of the image display medium are disposed near the first electromagnetic induction coil provided on the image display medium. The power supply device includes a second electromagnetic induction coil that supplies a magnetic flux so that an electric field is formed in the power supply device, and a magnetic flux variable unit that changes the magnetic flux generated from the second electromagnetic induction coil.
[0021]
Further, according to the present invention, in the image forming apparatus for an image display medium on which light can be written, the first electrode and the second electrode of the image display medium are disposed near the first electromagnetic induction coil provided on the image display medium. A power supply device having a second electromagnetic induction coil for supplying a magnetic flux so that an electric field is formed between the power supply device and a magnetic flux varying unit for changing an amount of magnetic flux generated by the second electromagnetic induction coil; And an exposure device having scanning means for irradiating writing light on the surface of the image display medium and scanning means for moving the image display medium.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of an image display medium and an image forming apparatus thereof according to the present invention will be described.
[0023]
In the embodiment of the present invention, each electrode terminal connected to the upper electrode and the lower electrode has a hermetically sealed structure so as not to be exposed to the atmosphere, and is not affected by natural discharge or the like. Therefore, even when the electrode terminals are sealed, an electromagnetic induction coil is embedded in the sealed structure so that a voltage can be supplied from the outside to the upper electrode and the lower electrode. And, when an electric field is generated between the upper electrode and the lower electrode, an image forming apparatus having a power supply device provided with an external electromagnetic induction coil capable of supplying a magnetic flux to the electromagnetic induction coil from outside the sealed structure was prepared. .
[0024]
Therefore, the image display medium according to the present embodiment specifically includes a transparent upper electrode, a lower electrode, an electromagnetic induction coil connected to both electrodes, an insulating layer provided on both electrodes, The insulating display particles having different colors and different charging characteristics are formed in an integrated structure that is hermetically closed so as to be shielded from the outside. Then, a switch that can be turned on and off from the outside is provided between the electromagnetic induction coil and the upper electrode or the lower electrode, and the switch is turned on only when an electric field is generated between the electrodes. A polar electric field is obtained. This switch is for preventing the backflow of charges after the end of rewriting.
[0025]
With such a configuration of the image display medium, an electric field can be applied using the connection terminal that is not exposed to the atmosphere, and image display can be rewritten by moving particles. Since the electrode terminal is not exposed, the electric charge of the insulating display particles is not affected by spontaneous discharge or the like even when left for a long time.
[0026]
In addition, the lower electrode and the lower substrate are also formed of a transparent material, and have a structure in which a composite layer of an insulating layer and a photoconductive layer is provided. By selectively irradiating the lower substrate with light from the outside, the photoconductive layer is formed. , And by moving only the desired insulating display particles, an arbitrary image can be displayed.
[0027]
Furthermore, the lower electrode and the lower substrate are also formed of a transparent material, and have a structure in which a composite layer of an insulating layer and a photoconductive layer is provided, and a color filter is provided on the upper substrate to correspond to the pixels of the color filter on the upper substrate. By exposing the photoconductive layer at the desired position, an arbitrary color image can be displayed.
[0028]
The image forming apparatus used for the image display medium of the present embodiment includes an electromagnetic induction coil that can supply a magnetic flux in proximity to the electromagnetic induction coil that is integrally sealed in the image display medium, and further scans the entire width of the image display medium. And an image display medium feeding device. With this configuration, a desired image can be formed without using a pixel electrode as an image display medium.
[0029]
Next, the image display medium of the present embodiment will be described with reference to the drawings.
[0030]
FIG. 1A is a schematic cross-sectional view showing a specific example of a dry-type image rewritable image display medium according to the present embodiment. Here, for convenience of illustration, one end of the image display medium is shown, and in particular, only the side where the electromagnetic induction coil is connected to each electrode is shown. As an example of being encapsulated between the upper electrode and the lower electrode, a case of a display medium having black particles and white particles having different charging characteristics between the electrodes is shown, but it is not limited to this format, and the display is performed between the electrodes. An insulating solvent or the like can be included in addition to the particles, and the desired color of the particles can be used.
[0031]
The image display medium of FIG. 1A uses black particles 8 and white particles 9 having different charging characteristics. The black particles have positive charging characteristics and the white particles have negative charging characteristics. In the image display medium, an upper substrate 1 and a lower substrate 2 made of a transparent material are arranged to face each other via a spacer 7 and a partition 11, and a transparent upper electrode 3 and an insulating layer 4 are laminated on the inner surface side of the upper substrate 1. The lower electrode 5 and the lower electrode 6 are laminated on the inner surface side of the lower substrate 2.
[0032]
A display medium in which black particles 8 and white particles 9 are dispersed in a gas 10 is sealed in a space surrounded by the insulating layers 4 and 6 and the partition 11. The insulating layers 4 and 6 function as a holding layer for display particles when an electric field is applied. Note that dry air or a gas containing an inert gas such as nitrogen can be used as the insulating fluid sealed in the space surrounded by the insulating layer and the partition.
[0033]
An electromagnetic induction coil 12 is connected to the upper electrode 3 and the lower electrode 5. The electromagnetic induction coil 12 is surrounded by a protective body 13 formed of, for example, the same insulating material as the substrate. The protector 13 serves to seal the connection between the electromagnetic induction coil 12 and each electrode from the atmosphere, and may be an insulating material different from the substrate material. However, when selecting the material of the protective body 13, it is necessary to supply a magnetic flux to the electromagnetic induction coil 12 from outside the protective body 13.
[0034]
The electromagnetic induction coil 12 generates a voltage for forming an electric field between the upper electrode 3 and the lower electrode 5 by electromagnetic induction by a magnetic flux supplied from outside the protection body 13. When this voltage is generated, the switch S that is turned on is inserted. In FIG. 1A, it is inserted between the upper electrode 3 and the electromagnetic induction coil 12, but may be inserted between the lower electrode 5 and the electromagnetic induction coil 12. Further, a capacitor can be connected between the upper electrode 3 and the lower electrode 5 in parallel with the electromagnetic induction coil 12.
[0035]
As the switch S, a pressure switch, a magnetically responsive reed switch, or the like can be used. That is, any device that can perform an on / off operation from the outside via the protection body 13 may be used. However, considering that the image display medium is a paper-like image display medium, it is preferable that the medium is as small and thin as possible. Of course, instead of the switch S, a capacitor, a resistor, a switch element, and the like are provided so that an electric field having a required polarity can be formed between the upper electrode 3 and the lower electrode 5 based on the voltage generated by the electromagnetic induction coil 12. It is also possible to provide a rectifier circuit according to.
[0036]
Note that, in FIG. 1A, the electromagnetic induction coil 12 sealed in the protective body 13 is simply schematically shown, and in fact, the electromagnetic induction coil 12 has, for example, a rectangular image display medium. In the case of having the shape of, on one side of the rectangle, on the inner surface of the substrate extended outward, or on the inner surface of the protective body 13, a thin conductive wire such as copper is planarized by the required number of turns. It is possible to arrange a coil that is wound in a specific manner. Alternatively, the coils can be formed on their inner surfaces with conductive wires by printed wiring technology.
[0037]
As described above, in the image display medium according to the present embodiment, the upper electrode, the lower electrode, and the electromagnetic induction coil are covered with the insulating substrate and the protective body. By being covered with the partition walls and the protective body, it is shielded from the outside air, and it is possible to prevent the charge of the display particles from spontaneously discharging into the air, thereby enabling a long-term image display.
[0038]
Next, the image display medium shown in FIG. 1A shows an initial state immediately after manufacturing, and FIG. 1B shows the image display medium supplied from an electromagnetic induction coil 15 provided in a power supply device 14. A state in which an initial electric field is formed between the electrodes and rewritten by electromagnetic induction by magnetic flux is shown. Here, it is shown that a negative voltage is applied to the lower electrode 5 and a positive voltage is applied to the opposing upper electrode 3. As a result, the black particles 8 adhere to the lower electrode 5 side and the white particles 9 adhere to the upper electrode 3 side, and the entire display medium is in a state indicating that white display has been performed.
[0039]
In the initial state, the display particles that have been aggregated by the Coulomb force are moved in the direction of the opposite polarity electrode according to the charging characteristics of the display particles by an electric field greater than the Coulomb force being formed between the electrodes by electromagnetic induction, Attaches to either electrode. Therefore, even when the electric field is cut off, the display particles are held on the respective electrode sides by Coulomb force and Van der Waals force due to the electrodes and the particle charges. When the polarity of the electromagnetic induction is switched, the black particles 9 move to the upper electrode 3 and the white particles 8 move to the lower electrode 5, respectively, so that the entire image display medium displays black.
[0040]
Similarly, when the black particles 9 are negatively charged and the white particles 8 are positively charged, when a positive voltage is applied to the lower electrode 5 and a negative voltage is applied to the upper electrode 3, the image display medium displays white. When the polarity of the voltage application is reversed, a black display is shown.
[0041]
Here, a method of supplying a magnetic flux from the electromagnetic induction coil 15 of the power supply device 14 shown in FIG. 1B to the electromagnetic induction coil 12 of the image display medium will be described with reference to FIG.
[0042]
In the example of the image display medium of the present embodiment, it is necessary to form a unidirectional electric field between the upper electrode and the lower electrode in order to put the display medium in a rewritten state. Even if a circuit is not prepared, a unidirectional electric field can be obtained between the upper electrode and the lower electrode by the electromagnetic induction coil 12 by a simple method.
[0043]
The graph of FIG. 2 shows the change of the magnetic flux generated by the electromagnetic induction coil 15, where the vertical axis represents the amount of magnetic flux Φ and the horizontal axis represents time t. A current corresponding to the amount of the magnetic flux is supplied from the power supply device 14 to the electromagnetic induction coil 15. Then, when the surface of the electromagnetic induction coil 15 is brought close to and parallel to the surface of the electromagnetic induction coil 12, the current is supplied to the electromagnetic induction coil 15.
[0044]
In the case of the magnetic flux change indicated by the solid line in FIG. 2, the magnetic flux amount Φ is gradually and gradually increased from time t1, and is rapidly reduced at time t2. As described above, during the predetermined time, the gradual increase and the rapid decrease are present, so that the rapid magnetic flux change rate within the predetermined time becomes dominant with respect to the voltage induction, and the both ends of the electromagnetic induction coil 12 Unipolar voltage can be induced. If necessary, in order to increase the supply power, the magnetic flux may be changed for a predetermined time as needed. FIG. 2 shows a case where the process is repeated three times.
[0045]
On the other hand, when it is desired to generate a voltage having the opposite polarity, the magnetic flux may be changed as indicated by a broken line in FIG. That is, when a voltage of the opposite polarity to that of the solid line is induced in the electromagnetic induction coil 12, the amount of magnetic flux is rapidly increased at time t1, and then gradually decreased until time t2. When the amount of magnetic flux is changed in this manner, a voltage having a polarity opposite to that shown by a solid line can be generated.
[0046]
As described above, a voltage of which polarity is selected can be induced in a non-contact manner with respect to the electromagnetic induction coil surrounded by the protective body. A control unit is provided in the power supply device 14 so as to have a magnetic flux change profile as shown in FIG. 2, and the magnitude of the magnetic flux amount can be adjusted. In the case where a special circuit such as a rectifier circuit is provided, such a magnetic flux change profile does not need to be provided, and the electromagnetic induction coil 15 may be supplied with a current that causes an alternating magnetic flux change. When a pressure switch is used as the switch S, when the power supply device 14 is mounted on the image display medium, the pressure switch may be turned on by its weight, or, of course, manually. It may be pressed on and turned on.
[0047]
The image display medium described above only displays black or white on the entire surface of the display medium. However, the image display medium shown in FIGS. did. As shown in FIG. 3, the basic configuration of the image display medium is the same as that shown in FIG. 1, and the same parts are denoted by the same reference numerals.
[0048]
In the image display medium of FIG. 3, a transparent electrode is used as the lower electrode 5, a composite layer of an insulating layer 6 and a photoconductive layer 16 made of at least a charge generating material is formed, and the lower electrode 2 is also formed of a transparent substrate. Has become. The photoconductive layer becomes a conductive layer by generating a hole-electron pair by exposing light of a desired wavelength, and functions as an insulating layer in an unexposed state.
[0049]
The electrical resistance of the composite layer of the photoconductive layer 16 and the insulating layer 6 provided on the lower electrode 5 changes during exposure, and is set to have the same value as that of the insulating layer 4 of the upper electrode 3. The relationship between the electrical resistance values is as follows: when the resistance value of the insulating layer is R1, the resistance value R2 of the unexposed composite layer is R1 <R2, and the electrical resistance value R3 of the composite layer at the time of exposure is: R1 = R3.
[0050]
In this image display medium as well, as in the case of FIG. 1, the electromagnetic induction coil 12 is integrally sealed together with the upper electrode 3 and the lower electrode 5 by the protective body 13, and applies a voltage between the electrodes. Is shielded from the outside, so that the image can be retained for a long period of time. The image display medium of FIG. 3 shows an initial state immediately after manufacturing and before rewriting, and shows a schematic cross section of an end portion of the display medium. Note that in this initial state, since no rewriting has been performed, the switch S is off.
[0051]
In the image display medium shown in FIG. 4, the switch S is turned on, and the magnetic flux is supplied from the electromagnetic induction coil 15 so that a relatively positive voltage is applied to the upper electrode 3 and a negative voltage is applied to the lower electrode 5. is there. At this time, the entire surface of the image display medium is exposed to desired light from the lower electrode 5 side under an electric field generated by the applied voltage. As a result, the electric resistance of the composite layer decreases, so that the effective voltage to the display particles increases, and the negatively chargeable white particles 9 move toward the upper electrode 3 and the positively chargeable black particles 8 move toward the lower electrode 5. It moves to a white display state over the entire display medium.
[0052]
Alternatively, when the polarity of the electromagnetic induction is switched, the upper electrode 3 side becomes black particles 8 and the lower electrode 5 side becomes white particles 9, and the entire surface is displayed in black. Similarly, when the black particles 8 are negatively charged and the white particles 8 are positively charged, when a positive voltage is applied to the lower electrode 5 and a negative voltage is applied to the upper electrode 3, white display is obtained. When a reverse electric field is formed, black display can be achieved. These black or white display states are initialization for rewriting the image display medium.
[0053]
Next, in FIG. 5, the same magnitude as the electric field formed by the electromagnetic induction in FIG. 4 is applied to the image display medium initialized and entirely white-displayed by the image display medium having undergone the initialization state shown in FIG. It is shown that a reverse electric field was formed by electromagnetic induction.
[0054]
At this time, only a predetermined portion of the photoconductive layer 16 is exposed from the lower electrode 5 side with writing light L by an exposure device capable of forming a minute spot. As a result, the electrical resistance of the photoconductive layer 16 in the exposed portion is reduced, and the display particles are moved, so that the black particles 8 and the white particles 9 are exchanged only in the exposed portion. For the unexposed portion, the electrical resistance of the photoconductive layer 16 does not change, and the effective voltage applied to the display particles does not change and remains small, so that the display particles do not move. Therefore, a desired image can be formed by applying a voltage by electromagnetic induction and performing desired writing and exposure on the photoconductive layer.
[0055]
Next, in the conventional image display media, it was possible to rewrite while a monochrome display, for example, a monochrome display using black particles and white particles was performed, but the image display medium shown in a schematic cross section in FIG. Now, color display is possible. In this case, the basic configuration is the same as that of the image display medium for monochrome display, but a composite layer of an insulating layer 6 and a photoconductive layer 16 made of at least a charge generating material is formed on the lower electrode 5. A transparent lower substrate 2 was provided, and a color filter F was provided on the upper substrate 1. FIG. 6 also shows an example of a medium in which positively chargeable black particles and negatively chargeable white particles are dispersed between electrodes, similarly to the above-described image display medium.
[0056]
The color filter F of the image display medium shown in FIG. 6 typically displays two pixels P1 and P2, and the pixel P1 includes a red filter R1, a green filter G1, and a blue filter. The pixel P2 is composed of a red filter R1, a green filter G2, and a blue filter B2, and the RGB filters are regularly arranged for each pixel.
[0057]
A color filter F is provided between the upper substrate 1 and the upper electrode 3. In the image display medium of the present embodiment, pixel electrodes corresponding to each of the RGB pixels or CMY pixels of the filter are required. In addition, full color display is possible by the additive color mixture method. Here, as an example, an image display medium using an RGB filter is used. Further, since the electromagnetic induction coil for applying a voltage between the electrodes is shielded from the outside by the protection body 13, even after the writing to the image display medium is completed, the image can be retained for a long period of time.
[0058]
FIG. 7 shows an initialization process for writing to the image display medium shown in FIG. 6, and is in a state similar to FIG. A state in which a positive voltage is applied to the upper electrode 3 and a negative voltage is applied to the lower electrode 5 by electromagnetic induction is shown. At this time, the entire surface of the image display medium is exposed to desired light from the lower electrode 5 side under an electric field due to the applied voltage.
[0059]
As a result, the electric resistance of the composite layer is reduced, the effective voltage to the display particles is increased, the negatively-charged white particles 9 move toward the upper electrode 3, and the positively-charged black particles 8 move toward the lower electrode 5. Move to the side. A white display is achieved by the additive color mixture by the color filter F over the entire display medium. Here, when the polarity of the electromagnetic induction is switched, the black particles 8 move to the upper electrode 3 side and the white particles 9 move to the lower electrode 5 side, and the upper electrode 3 absorbs the transmitted light. Therefore, the entire screen is displayed in black.
[0060]
Similarly, when the black particles 8 are negatively charged and the white particles 9 are positively charged, when a positive voltage is applied to the lower electrode 5 and a negative voltage is applied to the upper electrode 3, the display medium becomes a white display. When the reverse is applied, a black display is shown.
[0061]
Therefore, as shown in FIG. 8, the magnitude of the electric field formed by electromagnetic induction in FIG. Then, the opposite electric field is formed by electromagnetic induction.
[0062]
At this time, a desired portion is exposed from the lower electrode 5 side with writing light L of a light beam capable of forming a minute spot. As a result, the electrical resistance of the photoconductive layer 16 in the exposed portion is reduced and the effective voltage is increased, so that the black particles 8 and the white particles 9 are exchanged only in the exposed portion. At this time, for example, magenta exposes only the green pixel portion of the red (R), green (G), and blue (B) pixels, and moves the black particles 8 to the upper electrode 3 side. Can be displayed. By exposing a red pixel portion in the case of cyan and a blue pixel portion in the case of yellow, the portion can be displayed as a dark display.
[0063]
Similarly, as shown in FIG. 8, in the case of a red display, the portions of the green pixels G1 and the blue pixels B1 in the RGB pixels are exposed with the writing lights L1 and L2, so that the two pixels are black. When the particles 8 are moved toward the upper electrode 3, a red display can be performed. In the case of green display, it is possible to perform display by exposing a portion of red and blue pixels and in the case of blue display, exposing the portion of red and green pixels with writing light.
[0064]
Therefore, a desired color image can be formed by forming an electric field by electromagnetic induction and exposing writing light to a desired portion of the photoconductive layer.
[0065]
In the above description, the image display is performed by forming the electric field using the electromagnetic induction coil on the image display medium of the present embodiment. FIG. 9 illustrates the image formation for forming the image on the image display medium of the present embodiment. It is the schematic explaining the specific example of an apparatus. The image forming apparatus includes at least an electromagnetic induction coil 15, a power supply 14 for generating various types of magnetic flux in the coil, an initializing exposure device 17, a light beam scanning device 18, and an image display medium feeding device 19. Contains.
[0066]
The initializing exposure device 17 has a role of exposing the entire lower surface of the display medium when an electric field is formed by the electromagnetic induction of the electromagnetic induction coil 12 provided in the image display medium. Is initialized. The light beam scanning device 18 scans the display medium with the writing light in one direction to expose a desired portion of the photoconductive layer. In FIG. 9, the feeding device 19 holds and moves the image display medium so that the horizontal scanning by the light beam scanning device 18 can be performed in the vertical direction. Alternatively, they are carried out.
[0067]
The image forming apparatus can be used for either the monochrome image display medium shown in FIGS. 3 to 5 or the full color image display medium shown in FIGS. 6 to 8.
[0068]
The rewritable image display medium in the present embodiment is realized by using the present display medium configured in a cell shape on a glass substrate or a film substrate. This cell has an arbitrary size, does not correspond to a display pixel, and prevents diffusion movement of display particles in the horizontal direction. The entire display medium can be displayed in black and white by controlling the polarity of the applied voltage generated by electromagnetic induction.
[0069]
Further, after white display is performed on the entire surface of the image display medium, an electric field of the opposite polarity is formed, and the photoconductive layer at a position corresponding to the three primary color pixels of the color filter provided on the upper substrate is formed using a light beam scanning device. By selectively performing optical writing, a desired color image can be displayed on a white display screen. Similarly, a desired color image display can be obtained by selectively exposing the entire black display.
[0070]
The display particles in the image display medium of the present embodiment are required to be two-color particles having different charging characteristics, but in order to obtain high contrast, a combination of black particles and white particles is required. desirable. As for the charging characteristics, if the black particles are positively charged, the white particles show a negative chargeability if the black particles are negatively chargeable, and the white particles show a positive chargeability if the black particles are negatively chargeable. The chargeability and the negative chargeability are relative values when both display particles are compared, and do not indicate an absolute charge polarity.
[0071]
It is desirable that the display particles have low cohesion between particles and high fluidity, but any particles having a desired particle size distribution can be used. For example, polystyrene, styrene-acrylate copolymer, styrene methacrylate copolymer, styrene-butadiene copolymer, styrene-maleate copolymer, polyethylene copolymer, polyester, epoxy resin, epoxy polyol resin Particles obtained by pulverizing and classifying a dispersion of a pigment and a charge control agent in a polyurethane, polyamide, aliphatic or alicyclic hydrocarbon resin, or spherical particles of a styrene-acrylate copolymer can be used. . In addition, inorganic white substances such as silica, alumina, and titania produced by a sol-gel method and the like are also included.
[0072]
In addition, these particles can be subjected to thermal and physical treatments and spheronization treatments as necessary to adjust the surface shape.
[0073]
Known pigments can be used as coloring pigments in the display particles. For example, black particles include carbon black and triiron tetroxide, and white pigments include titanium oxide, zinc oxide, and talc. Further, in order to impart desired charging characteristics, a known charge control agent can be included. Examples of positive charge control agents include nigrosine, triphenylmethane, and quaternary ammonium salts. Examples of negative charge control agents include azo complexes, salicylic acid complexes, and calixarenes. And boron-based compounds.
[0074]
The display particles can have charging characteristics suitable for switching images when voltage is applied. Alternatively, in order to improve fluidity, an external additive such as silica, alumina, or titania, which is often used for toner, or a small amount of carbon fluoride which is known to exhibit good movement as insulating particles, is used. May be immobilized. Further, a surface treatment may be performed with a silicon-acryl polymer, a fluorine-based polymer, or the like.
[0075]
As the photoconductive layer used in the image display medium of the present embodiment, a known charge generation material used for an electrophotographic photoreceptor can be used. For example, organic pigments such as azo pigments, quinone pigments, perylene pigments, indigo pigments, thioindigo pigments, phthalocyanine pigments, quinacdrine pigments, and inorganic materials such as amorphous silicon, amorphous selenium, cadmium sulfide, and zinc oxide Can be mentioned.
[0076]
As the binder resin that can be used for the photoconductive layer, a polymer capable of forming an electrically insulating film is preferable, and examples of such a polymer include polycarbonate, polyester, methacrylic resin, acrylic resin, and polystyrene. Vinyl chloride, polyvinylidene chloride, polystyrene, silicone resin, silicone-alkyd resin and the like are used. The binder resin is not limited to these, and these binder resins can be used alone or in combination of two or more. Further, the same insulating resin can be used for the insulating film, the partition, and the protective body in the present image display medium.
[0077]
A charge transport material may be dispersed in the binder resin together with the charge generation material to form a photoconductive layer. Examples of the charge transport material used in the photoconductive layer include a stilpene compound, an arylamine compound, and a hydrazone compound.
[0078]
The number of turns of the coil for forming an electric field between the electrodes by electromagnetic induction of the image display medium of the present embodiment is set so that a desired voltage is obtained. Further, the coil may be provided with a switching tap so that the applied voltage between the electrodes can be changed as necessary.
[0079]
Similarly, the number of turns of the electromagnetic induction coil of the image forming apparatus that provides mutual induction to the electromagnetic induction coil of the image display medium by an external magnetic field is set so that a desired voltage is obtained, and the number of turns is changed as necessary. Switching taps that can be provided can also be provided.
[0080]
Further, the image display medium can switch the display particles more stably by incorporating a known device such as a pressure switch, a capacitor, or a resistor between the electromagnetic induction coil and the upper electrode and the lower electrode as necessary. In addition, the circuit can be designed.
[0081]
The exposure apparatus used in the image forming apparatus used for the image display medium of the present embodiment uses a scanning optical system to scan a laser light source one-dimensionally or two-dimensionally, a fluorescent display tube, a plasma light-emitting element, and an EL light-emitting element. A device or the like constituted by a one-dimensional optical writing or two-dimensional optical writing device in which elements, LED light emitting elements, and the like are arranged in a line or a plane can be used. Alternatively, a photomask may be provided, or a combination of a light source and a mirror capable of performing exposure by reflected light may be used.
[0082]
Further, the image forming apparatus of the present embodiment has an image display medium feeding device suitable for performing writing with a light beam scanning device quickly and precisely. For this feeding device, a known transport technology used in an electrophotographic printer and a printing machine can be used.
[0083]
As the transparent electrode in the image display medium of the present embodiment, a transparent electrode formed mainly of indium and tin on a glass surface or a transparent film can be used. Further, as the display particles, all of the above-described types of particles can be used, and display particles previously microencapsulated can be used as a method of enclosing between the electrodes.
[0084]
Next, a specific embodiment of the image display medium according to the present invention will be described. However, here, the image display medium is exemplified, and the present invention is not limited to the following embodiments. In addition, in order to form an electric field between the electrodes, power is supplied by the electromagnetic induction coil. In addition to the dry image display medium using gas as an insulating fluid in which display particles are dispersed, migration using an insulating liquid is also used. It can also be applied to a type image display medium.
[Example 1]
(Preparation of Display Particles) Carbon black and a charge control agent (triphenylmethane derivative, Clariant) are dispersed, crushed, classified, and externally added to a polyester resin (manufactured by Mitsubishi Rayon), and are positively charged with a central particle diameter of 10 μm. Black particles were obtained.
[0085]
Similarly, titanium oxide and a charge stabilizer (modified polyester salt, Clariant) were dispersed, crushed, classified, and externally added to the polyester resin to obtain negatively-chargeable white particles having a center particle diameter of 10 μm.
(Preparation of Insulating Layer) A binder (polycarbonate, manufactured by Mitsubishi Gas Chemical) was dissolved in tetrahydrofuran, applied to a PET film substrate with an ITO film by a doctor bar, and dried to form an insulating layer.
(Production of Particle Display Cell) A space is created by sandwiching a 100 μm transparent film between both substrates of a lower electrode having a charge generation layer made of a photoconductive layer and an upper electrode having an insulating layer. A mixture of black particles and white particles was sealed in the space together with dry air, an electromagnetic induction coil was attached, and a display cell was formed.
(Display operation) When a negative voltage of 300 V is applied to the ITO lower electrode by an induction magnetic field using an external electromagnetic induction coil, the upper electrode side shows white on the entire surface, or when a positive voltage of 300 V is applied, the entire surface becomes white. The display became black.
[Example 2]
(Preparation of Display Particles) Carbon black and a charge control agent (triphenylmethane derivative, Clariant) are dispersed, crushed, classified, and externally added to a polyester resin (manufactured by Mitsubishi Rayon), and are positively charged with a central particle diameter of 10 μm. Black particles were obtained. Similarly, titanium oxide and a charge stabilizer (modified polyester salt, Clariant) were dispersed, crushed, classified, and externally added to the polyester resin to obtain negatively-chargeable white particles having a center particle diameter of 10 μm.
(Preparation of Composite Layer of Photoconductive Layer and Insulating Layer) One part of a charge generation material (titanyl phthalocyanine) and one part of a binder (polycarbonate, manufactured by Mitsubishi Gas Chemical) are dissolved in tetrahydrofuran, and ITO is used as a lower electrode substrate by a doctor bar. It was applied on a PET film substrate with a film and dried to form a photoconductive layer.
[0086]
A binder (polycarbonate, manufactured by Mitsubishi Gas Chemical Co., Ltd.) dissolved in tetrahydrofuran was applied onto the photoconductive layer by spin coating, and dried to form a composite layer of an insulating layer and a photoconductive layer.
(Formation of Insulating Layer) A binder (polycarbonate, manufactured by Mitsubishi Gas Chemical) was dissolved in tetrahydrofuran, applied on a color filter by a doctor bar, and dried to form an insulating layer.
(Preparation of Particle Display Cell) A 100 μm transparent film is sandwiched between both substrates of a lower electrode having a charge generation layer made of a photoconductive layer and an upper electrode having an insulating layer to form a space. A mixture of black particles and white particles was sealed in the space together with dry air, an electromagnetic induction coil was attached, and a display cell was formed.
(Display operation) When a negative voltage of 300 V is applied to the ITO lower electrode by an induction magnetic field using an external electromagnetic induction coil, the upper electrode side shows white on the entire surface, and when a positive voltage of 300 V is applied, a black display on the entire surface. It became.
(Color display operation) Wavelength 780 nm, exposure surface output 1 mW / cm ² Using the laser unit and an external induction magnetic field coil, an apparatus for performing voltage application, exposure, and color display on the image display medium of this example was manufactured. Using this device, a voltage of -300 V is applied to the lower electrode, and the entire surface is exposed to white from the lower electrode side. After that, a voltage of +300 V is applied to the lower electrode to obtain desired image data. A desired image display could be performed by partially writing and exposing with a laser beam.
[Example 3]
(Preparation of Display Particles) Carbon black and a charge control agent (triphenylmethane derivative, Clariant) are dispersed, crushed, classified, and externally added to a polyester resin (manufactured by Mitsubishi Rayon), and are positively charged with a central particle diameter of 10 μm. Black particles were obtained.
[0087]
Similarly, titanium oxide and a charge stabilizer (modified polyester salt, Clariant) were dispersed, crushed, classified, and externally added to the polyester resin to obtain negatively-chargeable white particles having a center particle diameter of 10 μm.
(Preparation of Composite Layer of Photoconductive Layer and Insulating Layer) One part of a charge generating material (titanyl phthalocyanine) and one part of a binder (polycarbonate, manufactured by Mitsubishi Gas Chemical) are dissolved in tetrahydrofuran, and an ITO film serving as a lower substrate is formed with a doctor bar. It was applied on a PET film substrate with a coating and dried to obtain a photoconductive layer.
[0088]
On the photoconductive layer, a binder (polycarbonate, manufactured by Mitsubishi Gas Chemical Co., Ltd.) dissolved in tetrahydrofuran was applied by spin coating, and dried to form a composite layer of an insulating layer and a photoconductive layer.
(Formation of Insulating Layer) A binder (polycarbonate, manufactured by Mitsubishi Gas Chemical) was dissolved in tetrahydrofuran, applied on a color filter by a doctor bar, and dried to form an insulating layer.
(Preparation of Particle Display Cell) A 100 μm transparent film is sandwiched between both substrates of a lower electrode having a charge generation layer made of a photoconductive layer and an upper electrode having an insulating layer to form a space. A mixture of black particles and white particles was sealed in the space together with dry air, a coil for electromagnetic induction was attached, and a color filter was provided on the upper substrate surface to form a display cell.
(Display operation) When a negative voltage of 300 V is applied to the ITO lower electrode by an induction magnetic field using an external electromagnetic induction coil, the upper electrode side exhibits white on the entire surface, and when a positive voltage of 300 V is applied, the entire surface is black. It was displayed.
(Color display operation) Wavelength 780 nm, exposure surface output 1 mW / cm ² Using the laser unit and an external electromagnetic induction coil, an apparatus for applying a voltage, exposing, and performing color display on the image display medium of this example was manufactured. Using this apparatus, a voltage of -300 V is applied to the lower electrode, the entire surface of the photoconductive layer is exposed from the lower electrode side to make a white display, and a voltage of +300 V is applied to the lower electrode to obtain a desired image. Data was written with laser light, partial exposure was performed, and a color image display was performed only on the portion where the writing and exposure were performed.
[0089]
【The invention's effect】
As described above, in the image display medium of the present invention, two kinds of display particles having different charging characteristics and different colors are sealed between the upper electrode and the lower electrode together with the medium, and an electric field is applied between the electrodes during image rewriting. Since the electromagnetic induction coil to be formed has a hermetically sealed structure so as to be shielded from the outside, even after the writing is completed, it is possible to prevent the electric charge of the display particles from spontaneously discharging, and to maintain the image for a long period of time.
[0090]
Further, since a magnetic flux is supplied from the electromagnetic induction coil of the image forming apparatus to the electromagnetic induction coil in the image display medium and a switch which is turned on only at the time of writing is inserted, an electric field between the upper electrode and the lower electrode is inserted. The formation can be realized by a simple circuit configuration, and the polarity and strength of the electric field between the upper electrode and the lower electrode can be arbitrarily changed by changing the magnetic flux supplied from the electromagnetic induction coil of the image forming apparatus. And the image rewriting process can be easily performed.
[0091]
Therefore, according to the present invention, an inexpensive image display medium or color image display medium which has good image contrast, is light, can hold an image for a long period of time, is rewritable, and can be rewritten.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view of an image display medium according to the present invention, illustrating the principle of rewriting by applying a voltage generated by an external electromagnetic induction coil.
FIG. 2 is a graph showing a change in magnetic flux in an external electromagnetic induction coil when a voltage is applied.
FIG. 3 is a schematic sectional view illustrating an initial state of an optically writable image display medium.
FIG. 4 is a schematic cross-sectional view illustrating a state where a voltage is applied in the case of an optically writable image display medium.
FIG. 5 is a schematic cross-sectional view illustrating an optically written state in the case of an optically writable image display medium.
FIG. 6 is a schematic sectional view illustrating an initial state in the case of an image display medium having a color filter.
FIG. 7 is a schematic cross-sectional view illustrating a state where a voltage is applied to an image display medium having a color filter.
FIG. 8 is a schematic cross-sectional view illustrating an optical writing state in an image display medium having a color filter.
FIG. 9 is a schematic diagram illustrating an optically writable image forming apparatus using an image display medium having a color filter.
[Explanation of symbols]
1. Upper substrate
2 ... Lower board
3: Upper electrode
4, 6 ... insulating layer
5 Lower electrode
7 ... Spacer
8 Black particles
9 white particles
10 ... gas
11 ... partition
12, 15 ... electromagnetic induction coil
13 ... Protector
14 Power supply unit
16 Photoconductive layer
17 ... Exposure device for initialization
18. Light beam scanning device
19 ... Feeding device
S: Pressure switch
L1 to L3: writing light
F ... Color filter
R ₁ , R ₂ … Red filter
G ₁ , G ₂ … Green filter
B ₁ , B ₂ … Blue filter

Claims (11)

At least one has a transparent conductive first electrode and a second electrode, and a plurality of display particles having different charging characteristics and colors are provided between the insulating layer on the first electrode and the insulating layer on the second electrode. In an image display medium encapsulated and moved by an electric field formed between the first electrode and the second electrode,
An electromagnetic induction coil connected to the first electrode and the second electrode, and sealed with the first electrode and the second electrode by an electrical insulator;
An image display medium, wherein the electric field is formed between a first electrode and a second electrode by supplying a magnetic flux to the electromagnetic induction coil. The image display medium according to claim 1, wherein the display particles are dispersed in an insulating fluid sealed between the opposing insulating layers. The image display medium according to claim 1, wherein the magnetic flux is supplied from another electromagnetic induction coil adjacent to the electromagnetic induction coil. The electromagnetic induction coil is connected to a first electrode or a second electrode via a switch,
The image display medium according to claim 3, wherein the switch is turned on when the magnetic flux is being supplied to the electromagnetic induction coil. The magnetic flux supplied from the other electromagnetic induction coil has a steep change and a gradual change in time,
The image display medium according to claim 3, wherein the polarity of the electric field is determined by an order of the steep change and the gentle change of the magnetic flux. The image display medium according to claim 3, wherein a rectifier circuit is connected between the electromagnetic induction coil and the first electrode or the second electrode. The image display medium according to any one of claims 3 to 6, wherein the electromagnetic induction coil is formed on the inner surface of the electric insulator at a peripheral portion of the first electrode and the second electrode. A photoconductive layer is formed between the insulating layer and the first or second electrode that is transparent conductive,
The image display medium according to claim 7, wherein writing light is applied to the photoconductive layer via the first electrode or the second electrode. The image display medium according to claim 8, wherein a color filter layer is formed on a surface of the first electrode or the second electrode facing the photoconductive layer. An electric field is formed between the first electrode and the second electrode of the image display medium in the vicinity of the first electromagnetic induction coil provided in the image display medium according to claim 1. A second electromagnetic induction coil for supplying magnetic flux,
Magnetic flux changing means for changing the magnetic flux generated from the second electromagnetic induction coil;
An image forming apparatus provided with a power supply device having: An electric field is formed between the first electrode and the second electrode of the image display medium in the vicinity of the first electromagnetic induction coil provided in the image display medium according to claim 8 or 9. A power supply device comprising: a second electromagnetic induction coil for supplying a magnetic flux; and a magnetic flux variable unit for changing an amount of magnetic flux generated by the second electromagnetic induction coil;
Irradiating the image display medium with writing light, scanning means for scanning the writing light on the surface of the image display medium, and an exposure apparatus having a feeding means for moving the image display medium,
An image forming apparatus comprising:

Images