JP5610144B2 - Driving method of electrochromic display device - Google Patents

Description

  The present invention relates to a method for driving an electrochromic display device, and more particularly, to a method for driving an electrochromic display device capable of multicolor display.

In recent years, electronic paper has been actively developed as an electronic medium replacing paper.
Since electronic paper is characterized in that the display device is used like paper, characteristics different from those of a conventional display device such as a CRT or a liquid crystal display are required. For example, it is a reflection type display device, has a high white reflectance and a high contrast ratio, can display a high definition, has a memory effect in display, can be driven even at a low voltage, is thin and light, and is inexpensive It is necessary to have characteristics such as Among these, in particular, as characteristics relating to display quality, there is a high demand for white reflectance and contrast ratio equivalent to paper.

Until now, as a display device for electronic paper, for example, a method using a reflective liquid crystal, a method using electrophoresis, a method using toner migration, and the like have been proposed. However, it is very difficult for any of the above methods to perform multicolor display while ensuring white reflectance / contrast ratio. In general, in order to perform multicolor display, a color filter is provided. However, if a color filter is provided, the color filter itself absorbs light, and the reflectance decreases. Furthermore, since the color filter divides one pixel into red (R), green (G), and blue (B), the reflectance of the display device is lowered.
When the white reflectance / contrast ratio is significantly reduced, the visibility is very poor and it is difficult to use as electronic paper.

On the other hand, as a promising technique for realizing a reflective display device without providing the color filter as described above, there is a method using an electrochromic phenomenon.
A phenomenon in which a redox reaction occurs reversibly and a color changes reversibly by applying a voltage is called electrochromism. An electrochromic display device is a display device that utilizes the coloring / decoloring (hereinafter referred to as color erasing) of an electrochromic compound that causes this electrochromic phenomenon. Since this electrochromic display device is a reflective display device, has a memory effect, and can be driven at a low voltage, it is a leading candidate for display device technology for electronic paper use, from material development to device design. R & D has been conducted extensively.

However, the electrochromic display device has a drawback in that the response speed of color development / decoloration is slow because of the principle of performing color development / decoloration using an oxidation-reduction reaction.
Patent Document 1 describes an example in which an electrochromic compound is fixed in the vicinity of an electrode to improve the response speed of color development and decoloration. According to the description in Patent Document 1, the time required for color development and decoloration, which has been about several tens of seconds, has been improved to about 1 second for both the color development time from colorless to blue and the color erase time from blue to colorless. Yes. However, this is not sufficient, and in the research and development of electrochromic display devices, it is necessary to further improve the response speed of color development and decoloration.

On the other hand, the electrochromic display device is expected as a multicolor display device because various colors can be developed depending on the structure of the electrochromic compound.
There are some known examples of multicolor display devices using such electrochromic display devices.

  For example, Patent Document 2 discloses a multicolor display device using an electrochromic compound in which fine particles of a plurality of types of electrochromic compounds are stacked. In the display device described in Patent Document 2, a multicolor display device in which a plurality of electrochromic compounds, which are polymer compounds having a plurality of functional functional groups having different voltages that exhibit color development, are stacked to form a multicolor display electrochromic compound. An example is given.

  Further, Patent Document 3 discloses a display device in which a plurality of electrochromic layers are formed on an electrode, and multiple colors are developed using a difference in voltage value or current value necessary for the color development. The display device described in Patent Document 3 has a display layer formed by laminating or mixing a plurality of electrochromic compounds that develop different colors and have different threshold voltages for color development and different charge amounts necessary for color development. An example of a multicolor display device is described.

  Furthermore, the present inventors disclosed an electrochromic display device having a configuration in which a plurality of display electrodes and a corresponding plurality of electrochromic layers are stacked on a display substrate in Patent Document 4. This electrochromic display device was able to perform a color display capable of individually developing a plurality of colors by a simple method.

The electrochromic display device of Patent Document 4 is an ideal reflective color display device that can display high whiteness and a wide color range.
However, with the driving method by applying a constant voltage described in Patent Document 4, it is possible to control the color density, but it is difficult to display many gradations such as 16 gradations.

  Accordingly, the present invention has been made in view of the above points, and an object thereof is to provide a driving method of an electrochromic display device capable of developing an arbitrary intermediate color by simple control.

In order to solve the above problems, the driving method of the electrochromic display device according to the present invention specifically has the technical features described in the following (1) to (2) .
(1): A display substrate, a counter substrate provided opposite to the display substrate, and the display substrate and the counter substrate are sandwiched between and stacked in this order from the display substrate side. A display substrate having a layer and spaced apart from each other; and a counter electrode provided opposite to the plurality of display electrodes, the display substrate being closest to the display substrate and the counter electrode And an electric resistance between one display electrode of the plurality of display electrodes and the other display electrode is larger than an electric resistance of the one display electrode. A method of driving an electrochromic display device, wherein a selection step of selecting one of the plurality of display electrodes, and applying a constant current between the one display electrode selected in the selection step and the counter electrode The elect that the one display electrode has Chromic layer anda color step of color development in a desired color density, (I) the selection step sequentially selects all the first display electrodes of the plurality of display electrodes, said color process, Each time one display electrode is selected in the selection step, the constant current is applied to the one display electrode for a certain period of time, all of the plurality of display electrodes are selected and the constant current is applied for a certain period of time, (II) When at least one of the electrochromic layers included in each of the plurality of display electrodes does not reach a desired color density, the above (I) is repeated until the desired color density is developed. This is a method for driving an electrochromic display device. However, in the selection step, among the electrochromic layers of each of the plurality of display electrodes, those that have already developed color with a desired color density are excluded from selection targets.

According to the configuration described in (1) above, it is possible to provide a driving method for an electrochromic display device that can display an arbitrary color with simple control and can perform color display.
Also, according to the configuration described in (1) above, it is possible to recognize an approximate display image before reaching a desired color density, and to drive a color electrochromic display device that can reduce the stress on the operator. A method can be provided.

(2) : The plurality of display electrodes develop a cyan color, a first display electrode having an electrochromic layer that develops a yellow color, a second display electrode that has an electrochromic layer that develops a magenta color, and the like. The method for driving an electrochromic display device according to (1) above, comprising a third display electrode that forms an electrochromic layer.

According to the configuration described in (2) above, it is possible to provide a driving method for a full-color electrochromic display device.

  ADVANTAGE OF THE INVENTION According to this invention, the drive method of the electrochromic display apparatus which can color any intermediate color by simple control can be provided.

It is sectional drawing which shows typically the structure in 1st Embodiment of the electrochromic display apparatus which can apply the control method of the electrochromic display apparatus which concerns on this invention. It is a figure which shows an example of a structure of a constant current drive circuit. It is a figure which shows an example of a structure of the constant current drive circuit in the control method of the electrochromic display apparatus which concerns on this invention.

  The driving method of the electrochromic display device according to the present invention is sandwiched between the display substrate 11, the counter substrate 12 provided facing the display substrate 11, the display substrate 11 and the counter substrate 12, and the display A plurality of display electrodes 13 stacked in this order from the substrate 11 side, each having an electrochromic layer 14 and spaced apart from each other, and a counter electrode 15 provided to face the plurality of display electrodes 13 , And an electrolyte 20 sandwiched between the display electrode 13a closest to the display substrate 11 and the counter electrode 15, and one display electrode 13 of the plurality of display electrodes 13 The display electrode 13 has an electric resistance larger than that of the one display electrode 13, and is a driving method of an electrochromic display device, wherein one of the plurality of display electrodes 13 is selected. A constant current is applied between the selection process to be selected, the one display electrode 13 selected in the selection process, and the counter electrode 15, and the electrochromic layer 14 of the one display electrode 13 has a desired color density. A color forming step for developing the color, and the selecting step and the color forming step are performed on each of the plurality of display electrodes 13.

Next, an electrochromic display device for carrying out the present invention will be described with reference to the drawings.
Although the embodiments described below are preferred embodiments of the present invention, various technically preferable limitations are attached thereto, but the scope of the present invention is intended to limit the present invention in the following description. Unless otherwise described, the present invention is not limited to these embodiments.

<Electrochromic display device 10>
With reference to FIG. 1, an electroelectrochromic display device to which the method for controlling an electrochromic display device according to the present invention is applicable will be described.
FIG. 1 is a cross-sectional view schematically showing a configuration in a first embodiment of an electrochromic display device to which an electrochromic display device control method according to the present invention can be applied. However, FIG. 1 shows an example of an electrochromic display device to which the electrochromic display device control method according to the present invention can be applied, and the electrochromic display device control method according to the embodiment of the present invention can be applied. The electrochromic display device is not limited to the configuration shown in FIG. In particular, the display device shown in FIG. 1 has three electrochromic layers stacked, but according to the present invention, any display device having two or more layers is applicable. In FIG. 1, the cell 19 partitioned by the spacer 18 formed of a well-known and commonly used material corresponds to one pixel, and a plurality of the electrochromic display devices 10 may be arranged.

In the electrochromic display device 10 used in the present invention shown in FIG. 1, a display electrode 13 and three electrochromic layers 14 provided in contact with the display electrode are laminated. In other words, three display electrodes 13 each having an electrochromic layer 14 (laminated) are laminated on the display substrate 11.
That is, the display substrate 11 includes a first display electrode 13a formed on the display substrate 11a, a first electrochromic layer 14a provided in contact with the first display electrode 13a, and a first electrochromic layer 14a. A first insulating layer 22a provided in contact with the first insulating layer 22a, a second display electrode 13b provided in contact with the first insulating layer 22a, and a second electroelectrode provided in contact with the second display electrode 13b. A chromic layer 14b, a second insulating layer 22b provided in contact with the second electrochromic layer 14b, a third display electrode 13c provided in contact with the second insulating layer 22b, and a third display And a third electrochromic layer 14c provided in contact with the electrode 13c.

  The electrochromic display device 10 can easily perform multicolor display by having the above-described structure. Since the first display electrode 13a, the second display electrode 13b, and the third display electrode 13c are provided separately via the first insulating layer 22a and the second insulating layer 22b, the counter electrode The potential of the first display electrode 13a for each of the 15 pixels, the potential of the second display electrode 13b for each pixel of the counter electrode 15, and the potential of the third display electrode 13c for each pixel of the counter electrode 15 The potential can be controlled independently. As a result, the first electrochromic layer 14a provided in contact with the first display electrode 13a, the second electrochromic layer 14b provided in contact with the second display electrode 13b, and the third display electrode 13c. The third electrochromic layer 14c provided in contact with each other can be independently developed and decolored.

  Since the first electrochromic layer 14a, the second electrochromic layer 14b, and the third electrochromic layer 14c are stacked on the display substrate 11, the first electrochromic layer 14a, The color development / decoloration pattern of the second electrochromic layer 14b and the third electrochromic layer 14c allows the color development of only the first electrochromic layer 14a, the color development of only the second electrochromic layer 14b, and the third electrochromic layer. Color development of only the layer 14c, color development by two layers of the first electrochromic layer 14a and the second electrochromic layer 14b, color development by two layers of the first electrochromic layer 14a and the third electrochromic layer 14c, second Electrochromic layer 14b and the third electrochromic layer Color development by two layers of the layer 14c, and color development by three layers of the first electrochromic layer 14a, the second electrochromic layer 14b, and the third electrochromic layer 14c can be changed, and multicolor display is possible. .

  In addition, as the first electrochromic layer 14a, the second electrochromic layer 14b, and the third electrochromic layer 14c, electrochromic layers that color yellow, magenta, and cyan are used, and the first display electrode 13a and the second electrochromic layer 14c are used. The electrochromic display device 10a can perform full-color display by independently controlling the potentials of the display electrode 13b and the third display electrode 13c.

Hereinafter, materials constituting the electrochromic display device will be described.
<Display electrode 13>
The material constituting the display electrodes 13a, 13b, and 13c is not particularly limited as long as it is a conductive material. However, since it is necessary to ensure light transmission, it is transparent and excellent in conductivity. A transparent conductive material is used. Thereby, the visibility of the color to develop can be improved more. As the transparent conductive material, inorganic materials such as tin-doped indium oxide (hereinafter referred to as ITO), fluorine-doped tin oxide (hereinafter referred to as FTO), and antimony-doped tin oxide (hereinafter referred to as ATO) can be used. In particular, any one of indium oxide (hereinafter referred to as In oxide), tin oxide (hereinafter referred to as Sn oxide) or zinc oxide (hereinafter referred to as Zn oxide) formed by vacuum film formation is used. The inorganic material is preferably included. In oxides, Sn oxides, and Zn oxides are materials that can be easily formed by sputtering, and are materials that can provide good transparency and electrical conductivity. Particularly preferable materials are InSnO, GaZnO, SnO, In ₂ O ₃ and ZnO.

<Display substrate 11>
Examples of the material constituting the display substrate 11 include glass and plastic. At this time, if a plastic film is used as the display substrate 11, a lightweight and flexible display device can be manufactured.

<Electrolyte layer 20>
As the electrolyte layer 20, a layer in which a supporting salt is dissolved in a solvent is used. For this reason, ionic conductivity is high.
As a material of the electrolyte layer 20, for example, an inorganic ion salt such as an alkali metal salt or an alkaline earth metal salt, a quaternary ammonium salt, an acid, or an alkaline salt can be used as the supporting salt. Specifically, LiClO ₄ , LiBF ₄ , LiAsF ₆ , LiPF ₆ , LiCF ₃ SO ₃ , LiCF ₃ COO, KCl, NaClO ₃ , NaCl, NaBF ₄ , NaSCN, KBF ₄ , Mg (ClO ₄ ) ₂ , Mg ( BF ₄ ) ₂ , tetrabutylammonium perchlorate, or the like can be used. Examples of the solvent include propylene carbonate, acetonitrile, γ-butyrolactone, ethylene carbonate, sulfolane, dioxolane, tetrahydrofuran, 2-methyltetrahydrofuran, dimethyl sulfoxide, 1,2-dimethoxyethane, 1,2-ethoxymethoxyethane, and polyethylene glycol. , Alcohols and the like are used. In addition, since it is not particularly limited to a liquid electrolyte in which a supporting salt is dissolved in a solvent, an ionic liquid, a gel electrolyte, or a solid electrolyte such as a polymer electrolyte is also used.

  The electrolyte layer 20 is preferably formed in a gel form or a solid form from the viewpoint of improving element strength, improving reliability, and preventing color diffusion. As a solidification method, it is preferable to hold the electrolyte and the solvent in the polymer resin. This is because high ionic conductivity and solid strength can be obtained. Furthermore, the polymer resin is preferably a photocurable resin. This is because the device can be manufactured at a low temperature and in a short time compared to thermal polymerization or a method of thinning the film by evaporating the solvent. Examples of the resin include, but are not limited to, urethane, ethylene glycol, polypropylene glycol, vinyl alcohol, acrylic, and epoxy.

Moreover, the function of a white reflective layer can also be given by disperse | distributing the color pigment particle 21a mentioned later in the electrolyte layer 20. FIG. Although it does not specifically limit as white pigment particle | grains 21a, Metal oxides, such as a titanium oxide, an aluminum oxide, a zinc oxide, a silicon oxide, a cesium oxide, an yttrium oxide, are mentioned.
When the electrolyte layer is cured with a photo-curing resin, if the amount of the white pigment particles 21a is increased, light is shielded, which tends to cause poor curing. Although depending on the thickness of the electrolyte layer, the preferred content is 10 to 50 wt%.
The thickness of the electrolyte layer is in the range of 0.1 to 200 μm. Preferably it is 1-50 micrometers. This is because if the electrolyte layer is thicker than this, electric charges are likely to diffuse, and if it is thinner than this, it is difficult to hold the electrolyte.

The electrolyte layer 20 is sandwiched between the display electrode 13a closest to the display substrate 11 and the counter electrode 15 among the plurality of display electrodes 13a, 13b, and 13c.
In other words, the cell 19 partitioned by the display electrode 13a closest to the display substrate 11, the counter electrode 15 and the spacer 18 is filled with the electrolyte (the electrolyte layer 20 is formed in the cell 19). It will be)

<Electrochromic layer 14>
For the electrochromic layers 14a, 14b, and 14c, a material that causes a color change by oxidation and reduction is used. As such a material, a known electrochromic compound such as a polymer, a dye, a metal complex, or a metal oxide is used.
Specifically, polymer-based, dye-based electrochromic compounds include azobenzene, anthraquinone, diarylethene, dihydroprene, styryl, styryl spiropyran, spirooxazine, spirothiopyran, thioindigo, tetrathiafulvalene Terephthalic acid, triphenylmethane, triphenylamine, naphthopyran, viologen, dipyridine, pyrazoline, phenazine, phenylenediamine, phenoxazine, phenothiazine, phthalocyanine, fluoran, fulgide, A low molecular organic electrochromic compound such as benzopyran or metallocene, or a conductive polymer compound such as polyaniline or polythiophene is used.

  Among the above, it is particularly preferable to include a dipyridine compound represented by the following general formula (1). Since these materials have a low color development / discoloration potential, even when an electrochromic display device having a plurality of display electrodes is configured, a good color value is exhibited by the reduction potential.

(Wherein R ₁ and R ₂ each independently represents an alkyl group or an aryl group which may have a substituent, and at least one of R ₁ and R ₂ is COOH, PO (OH) ₂ , Si (OC _k H _{2k + 1} ) having a substituent selected from _3. X represents a monovalent anion, k represents a positive integer, n represents 0, 1 or 2.
A represents an aryl group or a heterocyclic group which may have a substituent.

  These compounds are formed in contact with the display electrode 13, and particularly preferably, the electrochromic compounds 16 a, 16 b, and 16 c are adsorbed or bonded to the nanostructure semiconductor material 17 and are in contact with the electrode.

  In this embodiment, the electrochromic compound 16 is fixed so as not to move, and electrical connection only needs to be ensured so as not to prevent the transfer of electrons accompanying the oxidation / reduction of the electrochromic compound 16. Compound 16 and nanostructured semiconductor material 17 may be mixed to form a single layer.

  The material of the nanostructure semiconductor material 17 is not particularly limited, but titanium oxide, zinc oxide, tin oxide, aluminum oxide (hereinafter referred to as alumina), zirconium oxide, cerium oxide, silicon oxide (hereinafter referred to as silica), yttrium oxide. , Oxygen boron, magnesium oxide, strontium titanate, potassium titanate, barium titanate, calcium titanate, calcium oxide, ferrite, hafnium oxide, tungsten oxide, iron oxide, copper oxide, nickel oxide, cobalt oxide, barium oxide, oxide A metal oxide mainly composed of strontium, vanadium oxide, aluminosilicate, calcium phosphate, aluminosilicate or the like is used. Moreover, these metal oxides may be used independently and 2 or more types may be mixed and used.

  In view of physical properties such as electrical properties such as electrical conductivity and optical properties, among the above listed nanostructured semiconductor materials 17 are titanium oxide, zinc oxide, tin oxide, alumina, zirconium oxide, iron oxide, When one kind selected from magnesium oxide, indium oxide, tungsten oxide, or a mixture thereof is used, multicolor display excellent in the response speed of color development and decoloration is possible. The shape of the nanostructured semiconductor material 17 is not particularly limited, but a shape having a large surface area per unit volume (hereinafter referred to as specific surface area) is used in order to efficiently carry the electrochromic compound. By having a large specific surface area, the electrochromic compound is efficiently supported, and a display excellent in display contrast ratio of color development and decoloration is possible.

  A preferable film thickness range of the electrochromic layer 14 is 0.2 to 5.0 μm. When the film thickness is thinner than this range, it is difficult to obtain the color density. Further, when the film thickness is thicker than this range, the manufacturing cost increases, and the visibility tends to decrease due to coloring.

In the stacked configuration of FIG. 1, the resistance between the adjacent display electrodes of the first display electrode 13 a, the second display electrode 13 b, and the third display electrode 13 c is set so that the potential of one display electrode is opposed to the counter electrode 15. The resistance must be large enough to be controlled independently of the potential of the other display electrodes with respect to the electrode 15. At least in the first display electrode 13a, the second display electrode 13b, and the third display electrode 13c, the resistance between the adjacent display electrodes is larger than the sheet resistance of any of the adjacent display electrodes. It must be formed as follows. That is, the electrical resistance between one display electrode of the plurality of display electrodes and the other display electrode is larger than the electrical resistance of the one display electrode.
The interelectrode resistance between the first display electrode 13a, the second display electrode 13b, and the third display electrode 13c is that of the first display electrode 13a, the second display electrode 13b, and the third display electrode 13c. When the sheet resistance is smaller than any one of the display electrodes, when a voltage is applied to any one of the first display electrode 13a, the second display electrode 13b, and the third display electrode 13c, a similar voltage is generated. It is applied to other display electrodes, and the electrochromic layer corresponding to each display electrode cannot be erased independently.
Each display electrode resistance is preferably 500 times or more the sheet resistance of each display electrode. In order to ensure the resistance value, it is preferable to form an insulating layer 22 described later.

The plurality of display electrodes 13 each having the electrochromic layer 14 has an arrangement configuration in which the display electrodes 13 are provided apart from each other.
Here, in the present invention, as described above, the resistance of each display electrode 13 and the resistance between the display electrodes 13 are remarkably different, so that the potential of each display electrode 13 is independent of the potentials of the other display electrodes 13. The state in which control is possible is called “separation”. That is, in the driving method of the electrochromic display device according to the present invention, the plurality of display electrodes 13 each having the electrochromic layer 14 in the electrochromic display device 10 are provided so as to be electrically separated from each other. In short, it is preferable that they are provided to be electrically insulated from each other.
Therefore, even if the display electrodes 13 are merely in structural contact (for example, the display electrodes 13 are partially in contact with each other via the electrochromic layer 14), if the potentials of the contacted display electrodes can be controlled independently, It belongs to the category of “separation”.

<Insulating layer 22>
The material of the insulating layers 22a and 22b is not particularly limited as long as it is porous, but organic materials and inorganic materials excellent in insulation, durability, and film formability can be used.
As a method for forming a porous film, a sintering method (using fine particles or inorganic particles that are partially fused by adding a binder or the like and utilizing pores formed between the particles), an extraction method (soluble in a solvent) After forming a constituent layer with an organic or inorganic substance and a binder that does not dissolve in the solvent, the organic or inorganic substance is dissolved in the solvent to obtain pores), and the polymer is foamed by heating or degassing etc. Known forming methods such as a foaming method, a phase change method in which a mixture of polymers is phase-separated by operating a good solvent and a poor solvent, and a radiation irradiation method in which pores are formed by radiating various types of radiation can be used. .

Specific examples include a polymer mixed particle film composed of inorganic nanostructured particles (SiO ₂ particles, Al ₂ O ₃ particles, etc.) and a polymer binder, a porous organic film (polyurethane resin, polyethylene resin), and a porous film. Examples include the formed inorganic insulating material film.
As this inorganic film, a material containing at least ZnS is preferable. ZnS has a feature that it can be deposited at high speed by sputtering without damaging the electrochromic layer or the like. Furthermore, ZnO—SiO ₂ , ZnS—SiC, ZnS—Si, ZnS—Ge, or the like can be used as a material containing ZnS as a main component. Here, the ZnS content is preferably about 50 to 90 mol% in order to maintain good crystallinity when the insulating layer 22 is formed. Therefore, particularly preferable materials are ZnS—SiO ₂ (8/2), ZnS—SiO ₂ (7/3), and ZnS—ZnO—In ₂ O ₃ —Ga ₂ O ₃ (60/23/10/7). is there.
By using such materials for the insulating layers 22a and 22b, a good insulating effect can be obtained with a thin film, and a decrease in film strength (ie, peeling of the film) due to multilayering can be prevented.

  When ZnS or the like is formed by sputtering as described above, a porous film such as ZnS can be formed by forming a porous particle film as an undercoat layer in advance. In this case, the nanostructured semiconductor material described above can be used as a particulate film. However, it is insulative to form a porous particle film containing silica, alumina, etc. separately to form a two-layer insulating layer. To preferred. By making the insulating layers 22a and 22b porous using such a method, the electrolyte layer 20 can penetrate into the insulating layers 22a and 22b and further the display electrodes 13b and 13c. Accordingly, the movement of ionic charges in the electrolyte layer is facilitated, and multicolor display excellent in the response speed of color development and decoloration is possible. The insulating layers 22a and 22b have a thickness in the range of 20 to 1000 nm. When the film thickness is thinner than this range, it is difficult to obtain insulation. Further, when the film thickness is thicker than this range, the manufacturing cost increases, and the visibility tends to decrease due to coloring.

<Counter substrate 12 and counter electrode 15>
The material of the counter substrate 12 is not particularly limited, and the same material as the display substrate 11 can be used. A display substrate 11 and a counter substrate 12 provided to face the display substrate 11 are provided with a plurality of display electrodes 13 each having the electrochromic layer 14 described above and a counter electrode provided to face the display electrode 13. It is sandwiched in this order.
The material of the counter electrode 15 is not particularly limited as long as it is a conductive material. When a glass substrate or a plastic film is used as the counter substrate 12, the counter electrode 15 may be made of a transparent conductive film such as ITO, FTO, or zinc oxide, or a conductive metal film such as zinc or platinum, or carbon. Used. The counter electrode 15 made of these transparent conductive film or conductive metal is formed on the counter substrate 12 by vacuum film formation or wet coating. On the other hand, when a metal plate such as zinc is used as the counter electrode 15, the counter substrate 12 also serves as the counter electrode 15.
Furthermore, stable color development and decoloration can be achieved by forming, on the counter electrode, a material that causes a reverse reaction of the redox reaction caused by the electrochromic layers 14a, 14b, and 14c. That is, when the electrochromic layer develops color by oxidation, a reduction reaction occurs. When the electrochromic layer develops color by reduction, a material that causes oxidation reaction is used as the counter electrode 15 or on the counter electrode surface. The reaction of color development / decoloration in the chromic layers 14a, 14b, 14c becomes more stable.

The white reflective layer 21 scatters and reflects light incident from the display substrate 11 side. As a material of the white reflective layer 21, in addition to metals and semimetals, inorganic compound films such as oxides, ticks and sulfides, and titanium oxide, aluminum oxide, zinc oxide, silicon oxide, oxide Examples thereof include a white pigment particle film made of metal oxide particles such as cesium and yttrium oxide. In order to impart permeability to the inorganic compound film, it is necessary to form it in the same form as the insulating layer, and in order to obtain effective scattering, the particle size of the underlayer should be 100 to 400 nm with high scattering efficiency. preferable. The metal oxide particle film can be easily formed by coating and forming as a paste dispersed in a solution. A particularly preferred material is titanium oxide particles.
In addition, the film thickness of the white reflection layer 21 exists in the range of 0.1-50 micrometers, More preferably, it is 0.5-5 micrometers. When the film thickness is thinner than this range, it is difficult to obtain a white reflection effect. Moreover, when the film thickness is thicker than this range, it becomes difficult to achieve both permeability and film strength.
However, even if the titanium oxide particle-containing layer is used, the film strength tends to be insufficient if the film thickness is increased to the maximum reflectivity. Therefore, it is preferable to form the white reflective layer in a two-layer configuration of a white reflective layer that provides film strength and a white electrolyte layer in which the electrolyte layer 20 is mixed with white pigment particles 21a.

<First Embodiment of Driving Method of Electrochromic Display Device>
In the first embodiment of the electrochromic display device driving method of the present invention, a plurality of display electrodes 13 are sequentially selected one by one with respect to the above-described electrochromic display device, and fixed to the counter electrode 15. By applying current until a desired color density is obtained, each electrochromic layer 14 in contact with each display electrode 13 is sequentially colored.

  An electrochromic compound develops and decolors by causing an oxidation / reduction reaction by charge transfer. In other words, it is an element in which the color development reaction and decoloration reaction are controlled by the amount of applied charge. Conversely, the color density can be precisely controlled by controlling the amount of applied charge. Can be displayed. Since the amount of charge is expressed by the product of current and time, the color density is easily controlled in the driving method of the electrochromic display device of the present invention in which a constant current is applied for a certain time until a desired color density is reached. be able to.

  Since constant current drive already has LED (Light Emitting Diode) and organic EL (electroluminescence) drive elements and drive methods, which are current drive elements as well as electrochromic elements, these can be used.

FIG. 2 is a diagram illustrating an example of the configuration of the constant current drive circuit.
Referring to FIG. 2, the load 110 includes an electrochromic element. One end of the load 110 is connected to the power supply terminal 3, the other end is connected to the drain of the constant current driving transistor 8, and the source of the transistor 8 is grounded. Connect to terminal 4.
Further, a charge retention capacitor 100 is connected between the gate of the transistor 8 and the ground terminal 4.
One end of the switch transistor 9 is connected to the connection point between the charge holding capacitor 100 and the transistor 8, and the gate of the switch transistor 9 serves as the control terminal 2 to control conduction / cutoff of the transistor 9. The constant current supplied to the load 110 is turned on and off via the.
The other end of the switching transistor 9 is connected to the gate and drain of the transistor 7 having the same conductivity type as that of the transistor 8, and the source of the transistor 7 is connected to the ground terminal 4.
Transistors 7 and 8 constitute a current mirror circuit through a switching transistor 9.
In FIG. 2, the polarity (conductivity type) of the switching transistor 9 is not shown, but either N or P channel MOS transistor may be used.
The gate and drain of the transistor 7 are connected to the source of the source follower transistor 5 via the resistor 6.
The transistor 5 has a gate connected to the input terminal 1 and a drain connected to the power supply terminal 3. The current value of the current mirror circuit composed of the transistors 7 and 8 is determined by the voltage generated across the resistor 6.

  In FIG. 2, when a signal voltage is applied to the input terminal 1, the drain current I1 of the transistor 7 constituting the current mirror circuit can be expressed by the following equation (A).

I1 = (V1-VGS5-VGS7) / R6 (A)

  However, V1 is the voltage of the input terminal 1, VGS5 and VGS7 are ON voltages between the gates and sources of the transistors 5 and 7, and R6 is the resistance value of the resistor 6.

  Therefore, the current shown in the above formula (A) flows from the drain to the source of the transistor 7 and is converted into a voltage as the gate-source voltage of the transistor 7. When a control signal is applied to the control terminal 2 and the switching transistor 9 is in a conducting state, the gate-source voltage of the transistor 7 obtained by converting the current I1 shown in the above equation (A) into a voltage is passed through the switching transistor 9. Thus, the charge holding capacitor 100 and the gate of the transistor 8 are driven. Since the transistors 7 and 8 constitute a current mirror circuit, a current proportional to the current given by the above equation (A) flows as the drain current of the transistor 8 to drive the load 110 at a constant current.

  The electrochromic display device used in the present invention has a configuration in which a plurality of display electrodes 13 and an electrochromic layer 14 are laminated. Therefore, when the general constant current driving element of FIG. 2 is used, a switch mechanism for selecting the display electrode 13 is provided between the plurality of display electrodes 13 of the electrochromic element 10 and the power supply terminal 3, and each display electrode 13 is provided. Colors individually.

  An example of the configuration of the constant current driving circuit in the control method of the electrochromic display device according to the present invention is shown in FIG. The example of FIG. 3 is an example in which a display device having three display electrodes 13a, 13b, 13c and electrochromic layers 14a, 14b, 14c is applied to the load 110, and each display electrode 13 portion is denoted by 110a, 110b, 110c. Connecting. The power supply terminal 3 develops color while sequentially switching 110a, 110b, and 110c via the switch device 120.

  That is, one of the display electrodes 13a, 13b, and 13c is selected and selected, a constant current is applied between the selected one display electrode 13 and the counter electrode 15, and the display electrode 13 has the electro The chromic layer 14 is colored with a desired color density, and this selection / coloring is performed on each of the display electrodes 13a, 13b, and 13c, thereby achieving a desired display.

<Second Embodiment of Driving Method of Electrochromic Display Device>
In the second embodiment of the driving method of the electrochromic display device of the present invention, each electrochromic layer 14 is brought to a desired color density by intermittently applying a constant current to the selected one display electrode 13 a plurality of times. Let the color develop.
Since general electrochromic compounds have memory characteristics, even if current application is stopped during color development, the color will not be erased immediately. When current is applied again, a color development reaction occurs again from the continuation of the color development state. Therefore, it is not necessary to develop a color density to a desired color at once, and current can be applied intermittently multiple times.
According to the present embodiment, it is possible to suppress adverse effects caused by continuing to apply current until a desired color density is achieved, that is, destabilization of the current value due to factors such as heat generation, so that a constant current can be stably electrochromic. Since it can be applied to the layer 14, stable and high-quality image display can be performed.

<Third Embodiment of Driving Method of Electrochromic Display Device>
In the third embodiment of the driving method of the electrochromic display device of the present invention, gradation display is performed according to the number of application times when a constant current is intermittently applied to the selected one display electrode 13 a plurality of times. The electrochromic layer 14 is formed by setting the application time per one time to be equal to or less than the application time necessary to develop the gradation of the lowest color density, and applying current once or more until the desired color density is reached. Let the color develop.
By using the driving method of the present embodiment, gradation display can be performed simply by setting the number of times of application, so that display can be performed with easy digital control. It is also possible to perform gradation display with a duty ratio of ON / OFF by using a 60 Hz or 120 Hz control driver used in an existing display as it is.

<Fourth Embodiment of Driving Method of Electrochromic Display Device>
In the fourth embodiment of the driving method of the electrochromic display device of the present invention, a constant current is applied until the electrochromic layer 14 in contact with the selected one display electrode 13 develops a desired color density, and then the following method is performed. The display electrode 13 is selected.
When the driving method of the present embodiment is used, the display electrode 13 side may be switched as many times as the number of display electrodes 13. For example, in the case of an electrochromic display device in which three display electrodes 13a, 13b, and 13c each having an electrochromic layer for coloring yellow, magenta, and cyan are stacked, one of the power supply electrodes is used as one display electrode 13a, for example, yellow coloring. Select the electrode to create the desired yellow image. Next, another display electrode 13b, for example, a magenta coloring electrode, is selected to create a desired magenta image. At this point, an image in which yellow and magenta are superimposed is completed. The next remaining display electrode 13c, for example, a cyan coloring electrode is selected to create a desired cyan image. At this point, an image in which yellow, magenta, and cyan are superimposed is completed.
The advantage of the driving method of the present embodiment is that the number of times of power supply switching on the display electrode 13 side is small, so that the control mechanism of the switching portion can be simplified and the cost can be reduced.

<Fifth Embodiment of Driving Method of Electrochromic Display Device>
In the fifth embodiment of the driving method of the electrochromic display device of the present invention, a constant current is applied to one selected display electrode 13 for a certain period of time, and then the next display electrode 13 is switched, and all the display electrodes 13 are constant. After applying the constant current for a certain time, the application of the constant current again from the initially selected display electrode 13 for a certain period of time is repeated to develop each electrochromic layer 14 in contact with each display electrode 13 to a desired color density. That is.
For example, in the case of an electrochromic display device in which three display electrodes 13a, 13b, and 13c each having an electrochromic layer for coloring yellow, magenta, and cyan are stacked, one of the power supply electrodes is used as one display electrode 13a, for example, yellow coloring. An electrode is selected and a current is applied for a certain period of time or a certain number of times to create a yellow image halfway (a state where the color density is low overall).
Next, another display electrode 13b, for example, a magenta coloring electrode, is selected, and a magenta image is created halfway (a state in which the color density is low as a whole), similarly to yellow. At this point, an image with a low color density is created by superimposing yellow and magenta.
The next remaining display electrode 13c, for example, a cyan coloring electrode is selected, and a cyan image is created halfway (in a state where the color density is low as a whole) in the same manner as yellow and magenta. At this point, the color density of yellow, magenta, and cyan superimposed is low, but an image close to the completed image can be visually recognized.
From this state, yellow is selected again, the yellow color density is increased, and magenta and cyan are sequentially repeated until a desired color density is obtained.
The advantage of the driving method of the present embodiment is that the image can be visually recognized before the image is formed to the end. The user's stress can be reduced by being able to see quickly. In addition, when an incorrect image is displayed, it is possible to cancel and delete the image on the way, so that the operational feeling is improved.

  In other words, in the fifth embodiment, (I) the selection step sequentially selects all ones of the plurality of display electrodes 13, and the coloring step is performed every time one display electrode 13 is selected in the selection step. A constant current is applied to the one display electrode 13 for a certain period of time, and (II) the above (I) is repeated until all of the electrochromic layers 14 of the plurality of display electrodes 13 are colored with a desired color density. It is a drive method of a display apparatus. However, at this time, in the selection step, those in which the electrochromic layer 14 of the plurality of display electrodes 13 is already colored at a desired color density are excluded from selection targets.

<Sixth Embodiment of Driving Method of Electrochromic Display Device>
The sixth embodiment of the driving method of the electrochromic display device of the present invention includes an electrochromic layer that develops at least a yellow color, an electrochromic layer that develops a magenta color, and an electrochromic layer that develops a cyan color The display device is driven.
Since the electrochromic display device used in this embodiment has a stacked structure, a subtractive color mixture occurs when different colors are developed in each layer. Therefore, full color display can be realized by using an electrochromic layer that develops yellow, magenta, and cyan, which are the three primary colors in subtractive color mixing.

[Example 1]
(Preparation of display electrode and electrochromic layer)
An ITO film having a thickness of about 100 nm was formed on a 40 mm × 40 mm glass substrate by a sputtering method in a 20 mm × 20 mm region and a lead-out portion, thereby producing a first display electrode. The resistance in the first display electrode plane was about 200Ω. A titanium oxide nanoparticle dispersion liquid (trade name: SP210, manufactured by Showa Titanium Co., Ltd.) is spin-coated on this, and a titanium oxide particle film is formed by annealing at 120 ° C. for 15 minutes. A 5 wt% 2,2,3,3, tetrafluoropropanol solution of a viologen compound represented by the following structural formula (2) is spin-coated, and annealed at 120 ° C. for 10 minutes to form a titanium oxide particle and an electrochromic compound. 1 electrochromic layer was formed.

Next, an inorganic insulating layer of ZnS—SiO ₂ (8/2) was formed thereon with a film thickness of 25 nm to 150 nm by sputtering. Further, an ITO film having a thickness of about 100 nm is formed on this by forming a 20 mm × 20 mm region in a portion overlapping with the ITO film formed by the first display electrode, and a partial lead-out portion different from the first display electrode To form a second display electrode. The resistance in the second electrode plane was about 200Ω. Further, the resistance between the first display electrode and the second display electrode was 40 MΩ or more, which was an insulating state.

  A titanium oxide nanoparticle dispersion liquid (trade name: SP210, manufactured by Showa Titanium Co., Ltd.) is spin-coated thereon, and a titanium oxide particle film is formed by annealing at 120 ° C. for 15 minutes. A 1 wt% 2,2,3,3 tetrafluoropropanol solution of a viologen compound, which is a compound, is spin-coated, and a second electrochromic layer composed of titanium oxide particles and an electrochromic compound is formed by annealing at 120 ° C. for 10 minutes. As a result, a display substrate was obtained.

(Preparation of counter electrode)
A counter electrode made of tin oxide was formed on the entire surface of a 40 mm × 40 mm glass substrate. A solution obtained by adding 25 wt% of 2-ethoxyethyl acetate to a thermosetting conductive carbon ink (trade name: manufactured by CH10 Jujo Chemical Co., Ltd.) on the upper surface of the glass substrate on which the transparent conductive thin film of tin oxide is formed on the entire surface. The counter electrode was fabricated by spin coating and then annealing at 120 ° C. for 15 minutes.

(Production of electrochromic display device)
Tetrabutylammonium perchlorate as the electrolyte, dimethyl sulfoxide and polyethylene glycol (molecular weight: 200) as the solvent, and UV curing adhesive (trade name: PTC10, manufactured by Jujo Chemical Co., Ltd.) in a weight ratio of 1.2 to 5.4 to 6 to 16 A dispersion paste was prepared by adding 20 wt% of white titanium oxide particles (trade name: CR50, manufactured by Ishihara Sangyo Co., Ltd., average particle size: about 250 nm) to the solution mixed in the above. This was applied dropwise onto the above-described display substrate (lamination side of the electrochromic layer and the inorganic insulating layer), overlapped with the counter electrode surface, and cured by UV light irradiation and bonded from the counter substrate side to produce an electrochromic display device. The thickness of the electrolyte layer was set to 10 μm by mixing 0.2 wt% of bead spacers with the electrolyte layer.

(Color development test)
Color evaluation of the electrochromic display device produced above was performed.
The display device was irradiated with halogen light, and the reflected light was measured with a spectrophotometer (LCD5000 manufactured by Otsuka Electronics Co., Ltd.). Light incidence was performed from the 30 degree direction, and the intensity of reflected light in the 90 degree direction was measured. Using the standard white plate (Model 99002 manufactured by Yokogawa Electric Corporation) as a reference, the electrochromic display device produced as described above had a reflectance of 60% before color development. In the following Comparative Example 1 and Example 2 as well, a color development test was conducted by the same method.

When the first display electrode was connected to the negative electrode, the counter electrode was connected to the positive electrode, and a constant current of 0.6 mA was applied for 10 seconds using a potentiostat (ALS660C, manufactured by BAS Co., Ltd.), the reflectance became 14% and blue color was developed.
After decoloring by applying -0.6 mA for 10 seconds, a constant current of 0.6 mA was applied for 5 seconds. The reflectivity was 29% and a light blue color was developed.
After erasing again, when a constant current of 0.6 mA was applied for 3 seconds, the reflectance was 39%, and a lighter blue color was developed.
When the relationship between the application time and the reflectance is plotted, it can be plotted on an attenuation curve represented by a natural function, and the reflectance, that is, the color density can be easily controlled by the application time.

Next, when the second display electrode was connected to the negative electrode, the counter electrode was connected to the positive electrode, and a constant current of 0.4 mA was similarly applied for 10 seconds using a potentiostat, the reflectance became 24% and magenta color was developed.
After decoloring by applying −0.4 mA for 10 seconds, applying a constant current of 0.4 mA for 5 seconds gave a reflectance of 38% and a light magenta color was developed.
After erasing again, when a constant current of 0.4 mA was applied for 3 seconds, the reflectance became 46%, and a lighter magenta color was developed.
When the relationship between the application time and the reflectance is plotted as in the case of the first display electrode, it can be plotted on an attenuation curve represented by a natural function, and the reflectance, that is, the color density can be easily controlled by the application time.

Furthermore, after connecting the first display electrode to the negative electrode and the counter electrode to the positive electrode and applying a constant current of 0.6 mA for 10 seconds using a potentiostat, the second display electrode is set to the negative electrode and the counter electrode is set to the positive electrode. When a constant current of 0.4 mA was applied for 10 seconds, the reflectivity was 3.5% and dark purple color was developed.
After erasing the color by applying a reverse current, a constant current of 0.6 mA is applied to the first display electrode and 0.4 mA is applied to the second display electrode for 5 seconds. A purple color developed.
Similarly, when a constant current of 0.6 mA was applied to the first display electrode and 0.4 mA was applied to the second display electrode for 3 seconds, the reflectance was 18% and a pale purple color was developed.
When applied for 10 seconds, 5 seconds, and 3 seconds, respectively, the purple color did not change and only the color density changed. Therefore, the color density can be easily controlled without changing the color in the mixed color display.

[Comparative Example 1]
The same electrochromic display device as in Example 1 was produced.

(Color development test)
The reflectivity of the electrochromic display device produced above in the state before color development was 60%.
When the first display electrode was connected to the negative electrode, the counter electrode was connected to the positive electrode, and a constant voltage of 3.0 V was applied for 1 second using a potentiostat, the reflectance was 14% and blue color was developed.
After decoloring by applying −3.0 V for 1 second, applying a constant voltage of 3.0 V for 0.5 seconds gave a reflectance of 22%, producing a light blue color.
After erasing again, when a constant voltage of 3.0 V was applied for 0.3 seconds, the reflectance was 27%, and a lighter blue color was developed.
When the relationship between the application time and the reflectance is plotted, it is an attenuation curve, which is reproducible but not regular.

Next, when the second display electrode was connected to the negative electrode and the counter electrode was connected to the positive electrode, and a constant voltage of 2.6 V was applied for 1 second using a potentiostat in the same manner, the reflectivity was 24% and magenta color was developed.
After decoloring by applying −2.6 V for 10 seconds, a constant voltage of 2.6 V was applied for 5 seconds, and the reflectance was 33%, resulting in a light magenta color.
After erasing again, when a constant voltage of 2.6 V was applied for 3 seconds, the reflectance was 38%, and a lighter magenta color was developed.
When the relationship between the application time and the reflectance is plotted as in the case of the first display electrode, there is reproducibility but no regularity.

Further, the first display electrode is connected to the negative electrode, the counter electrode is connected to the positive electrode, a constant voltage of 3.0 V is applied for 1 second using a potentiostat, the second display electrode is set to the negative electrode, and the counter electrode is set to the positive electrode. When a constant voltage of 2.6 V was applied for 1 second, the reflectance was 3.5%, and a deep purple color was developed.
After erasing the color by applying a reverse current, a constant voltage of 3.0 V was applied to the first display electrode and a constant voltage of 2.6 V was applied to the second display electrode for 5 seconds. Although the color was purple at 8%, the color became purple with a greater blue taste compared to the case of applying for 10 seconds.
Similarly, when a constant voltage of 3.0 V was applied to the first display electrode and a constant voltage of 2.6 V was applied to the second display electrode for 3 seconds, the reflectivity was 11% and a light purple color was developed. However, when it was applied for 10 seconds, it turned purple with a greater blue tint than when it was applied for 5 seconds.
When applied for 10 seconds, 5 seconds, and 3 seconds, respectively, the purple color changed, and it was difficult to easily control the color density without changing the color in the mixed color display.

[Example 2]
The same electrochromic display device as in Example 1 was produced.

(Color development test)
When the first display electrode was connected to the negative electrode, the counter electrode was connected to the positive electrode, and a constant current of 0.6 mA was applied for 10 seconds using a potentiostat, the reflectance became 14% and blue color was developed. After decoloring, when a constant current of 0.6 mA was applied 10 times per second, the reflectivity was 14% as in the case of continuous application for 10 seconds, and blue color was developed.
After decoloring, when a constant current of 0.6 mA was applied 5 times per second, the reflectance was 29% as in the case of continuous application for 5 seconds, and blue color was developed.
The reflectance, that is, the color density can be easily controlled by the number of times of current application.

DESCRIPTION OF SYMBOLS 1 Input terminal 2 Control terminal 3 Power supply terminal 4 Ground terminal 5 Transistor 6 Resistance 7 Transistor 8 Transistor for constant current drive 9 Switch transistor 10 Electrochromic display device 11 Display substrate 12 Counter substrate 13 Display electrode 14 Electrochromic layer 15 Counter electrode 16 Electrochromic compound 17 Nanostructured semiconductor material 18 Spacer 19 Cell 20 Electrolyte layer 22 Insulating layer 100 Charge retention capacitor 110 Load 120 Switch device

Special table 2001-510590 gazette JP 2003-121883 A JP 2006-106669 A JP 2010-33016 A

Claims (2)

A display board;
A counter substrate provided facing the display substrate;
A plurality of display electrodes sandwiched between the display substrate and the counter substrate and stacked in this order from the display substrate side, each having an electrochromic layer and spaced apart from each other; and the plurality of display electrodes A counter electrode provided oppositely, and
An electrolyte sandwiched between the display electrode closest to the display substrate and the counter electrode;
An electrochromic display device driving method, wherein an electrical resistance between one display electrode of the plurality of display electrodes and another display electrode is larger than an electrical resistance of the one display electrode,
A selection step of selecting one of the plurality of display electrodes;
A color development step of applying a constant current between the one display electrode selected in the selection step and the counter electrode, and causing the electrochromic layer of the one display electrode to have a desired color density. ,
(I) The selection step sequentially selects all one display electrodes among the plurality of display electrodes, and the color development step displays the one display every time one display electrode is selected in the selection step. Applying the constant current to the electrodes for a certain period of time, selecting all of the plurality of display electrodes and applying the constant current for a certain period of time;
(II) When at least one of the electrochromic layers included in each of the plurality of display electrodes does not reach a desired color density, the above (I) is repeated until the desired color density is developed.
The driving method of the electrochromic display device, characterized in that.
However, in the selection step, among the electrochromic layers of each of the plurality of display electrodes, those that have already developed color with a desired color density are excluded from selection targets. The plurality of display electrodes include a first display electrode having an electrochromic layer for developing a yellow color, a second display electrode having an electrochromic layer for developing a magenta color, and an electrochromic layer for developing a cyan color. The method for driving an electrochromic display device according to claim 1, further comprising: a third display electrode.

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