JPH05224433A - Sheet like material for recording repeatedly usable - Google Patents

Abstract

PURPOSE:To attain excellent contrast and to unnecessitate a special electric source for erase and furthermore complicated wirings or electronic circuits by applying a material color developed by electrical oxidation-reduction on an electrode and applying a high-molecular solid electrolyte on the color develop ing material. CONSTITUTION:A transparent electrode layer 2 made of oxide of indium-tin or metal evaporated film is formed on a substrate 1 composed of a flexible plastic material. And an electrical color developing material layer 3 color developed-decolored by electrochemical oxidation-reduction reaction is applied on the transparent electrode layer 2. Finally the high-molecular solid electrolyte layer 4 is applied on the color developing layer 3. The film is partially color developed by impressing voltage to one point and is decolored by reverse potential. For example, by impressing voltage at a specific point, the surface of which is touched with a pen type electrode 7 to discolor an electrochromic material, an optional image is freely obtained. As a result, complicated electrodes or electronic circuits is unnecessitated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording sheet material (or recording film) to which an electrochromic display element is applied and which is strong against bending and can be repeatedly used.

[0002]

2. Description of the Related Art In the office, information processing equipment such as computers has come to be widely used, and accordingly, recording paper has come to be used in large quantities. However, most of the recording papers used are normal papers and are disposable. Moreover, with the increase in computer power,
The amount of recording paper used is increasing. Under such circumstances, global environmental issues have become more important in recent years, and disposable paper has become a problem. Therefore, in order to solve these problems, various studies have been made on a recording paper to which an electrochromic display element is applied and which can be repeatedly used, and many methods have been proposed. Some of them are shown below.

(1) Photochromic Recording Paper This recording paper has a structure in which a photochromic material is applied on a base film. This is intended to obtain an image by irradiating the photochromic layer with specific light to change the absorption wavelength of the photochromic layer. Since the photochromic material is reversible, it becomes a film that can be used repeatedly by erasing with a light having a wavelength different from that at the time of recording.

(2) Thermochromic Recording Paper This recording paper has a constitution in which a thermochromic material is applied on a base film. This is different from the photochromic described above, by changing the absorption wavelength of the thermochromic layer by applying a certain specific temperature,
It is intended to obtain an image. Since this thermochromic material is also reversible, it can be erased by applying a temperature different from that at the time of recording, and it becomes a film that can be repeatedly used.

(3) Polymer Liquid Crystal Recording Paper This recording paper has a structure in which a polymer liquid crystal is coated on a base film having a transparent electrode on one side, and a transparent electrode is attached to face it. .. In this film, a voltage is applied between the electrodes facing each other in advance to orient the polymer liquid crystal. When writing, when irradiated with light of a specific wavelength, the orientation of that part is disturbed and it looks discolored. Is. In the case of erasing, it is possible to apply a voltage to the opposing electrodes again, so that the film can be repeatedly used.

(4) Recording Paper Due to Structural Change This recording paper has a structure in which an organic material whose light scattering state changes between a crystalline state and an amorphous state is coated on a base film. This causes a structural change only in a region to which a temperature above crystallization is applied, and an image can be recorded due to the difference in light scattering in that region. Erasing is also possible by applying a certain range of temperature,
A film that can be used repeatedly. The above is a typical example of recording paper that can be used repeatedly, but many other recording papers have been devised.

[0007]

The above-mentioned recording paper has various problems as described below. (1) Photochromic recording paper This system has a small degree of freedom in selecting a writing wavelength and an erasing wavelength. Currently, special UV lamps are needed to erase. Further, if it is attempted to easily erase the image, the image may disappear even under visible light, and there is a drawback that a stable image cannot be obtained.

(2) Thermochromic recording paper This method requires heating when recording, and the heating temperature is considerably high, which may cause burns to the user. Also, the colors that change color are red, blue, and the like, and it is difficult to display in black and white, and high contrast is not obtained.

(3) Polymer liquid crystal recording paper In this system, an image is formed where the structure of the liquid crystal is changed and where it is not changed. In many cases, the image is formed by changing the transmittance of the liquid crystal. is doing. Therefore, when used with transmitted light, it is good, but when viewed with reflection, there is a drawback that good contrast cannot be obtained.

(4) Recording Paper Due to Structural Change This system, like the thermochromic recording paper, must be heated when recording, and the heating temperature is considerably high, which may cause burns to the user. .. Furthermore, this method is one in which the transmittance changes like polymer liquid crystal recording paper, and is good when used with transmitted light, but good contrast is obtained when viewed with reflection. There is a drawback to say no.

Further, there is a recording paper made of an electrochromic material in the related art, but in order to form an arbitrary image, electrodes must be arranged in a matrix form, the wiring becomes complicated, and the electrons for driving the same are formed. It has the drawback of requiring a circuit.

[0012]

SUMMARY OF THE INVENTION The present invention is an alternative to paper in printing and copying techniques that has good contrast, does not require a special erasing light source, and does not require complicated wiring or electronic circuitry. The present invention provides an electrochromic display device that can be used as a product.

That is, the present invention is a film in which an electrode is coated with an electrochromic material that develops color in an electrical redox state, and the polymer material is further coated on the electrochromic material. It is a film or sheet-like substance for recording which is repeatedly used and which is characterized in that the electrochromic display device is applied to the recording film and is erased by applying a reverse potential.

The present invention has only one electrode on the film, unlike the structure having a pair of electrodes facing each other like a normal electrochromic display element, and whether the solid polymer electrolyte is exposed on the surface. In this state, a striped independent electron conductive film is coated. The electrochromic material is discolored by touching the surface with, for example, a pen-type electrode and applying a voltage to a specific point.
Any image can be freely obtained. Therefore, complicated electrodes and electronic circuits are unnecessary. Also, the pen to input is
There is no danger of being burned because it does not raise the temperature in particular because it is only an electrode. Furthermore, since the applied voltage is not high, there is no fear of electric shock. The electrode of the present invention is preferably a transparent thin film electrode.

Further, since the present invention uses the electrochromic material, the memory function can be utilized similarly to the electrochromic material, and the written data is retained. When erasing is desired, it is possible to apply a voltage opposite to that used at the time of recording with the pen used for writing or another electrode having a large area.

The electrochromic material (material that develops or erases color by electrical redox) in the present invention may be a material that develops color by electrical reduction and then erases by electrical oxidation,
The reverse is also acceptable. An example of a recording sheet material in which white or colored paper or film is arranged as a substrate on the surface opposite to the surface of the thin-film electrode used in the present invention which is coated with the coloring material is a recording sheet material that can be repeatedly used. Is preferred as Further, the substrate may be a conductive film, and in this case, it may serve as both the substrate and the electrode.

(Embodiment) The present invention will be described below with reference to FIG. As shown in FIG. 1, the recording film (sheet-like substance) of the present invention uses one substrate (1). The substrate may be made of glass, but is preferably formed of a flexible plastic material, particularly an opaque material such as white, in order to enhance mechanical strength. A transparent electrode layer (2) made of an oxide of indium tin or a metal vapor deposition film is formed on the substrate. Further, the transparent electrode is covered with an electrochromic material layer (3) which develops and decolors by an electrochemical redox reaction. Examples of the coloring material that develops color in a reduced state include alkyl viologen, polyviologen, tungsten oxide (WO ₃ ), polyaniline, molybdenum oxide (MoO ₃ ), and the like. On the other hand, those that develop color in the oxidized state include Prussian blue (PB), polyvirol, polythiophene, indium hydroxide (Ir).
(OH) n) and the like. It is preferable that the color-forming material have a large absorbance and a marked difference in absorbance between the oxidized state and the reduced state. Finally, the solid polymer electrolyte (4) is coated on the coloring material. This polymer solid electrolyte is poly (oligooxymethacrylate)
(Hereinafter, abbreviated as PMEO) or a copolymer of (ω-methoxy) oligooxyethylene methacrylate and methyl methacrylate (hereinafter, abbreviated as P (MEO-MMA))
A polymer solid / inorganic metal salt complex is used. The partial structures of PMEO and P (MEO-MMA) are shown in Chemical Formulas 1 and 2 below.

[0018]

[Chemical 1]

[0019]

[Chemical 2]

The inorganic salts include LiClO ₄ and LiCl
Any of these can be used, but since the use of polyvalent ions causes a decrease in response speed, a salt that produces monovalent ions is desirable. A lead wire (6) for supplying a voltage from an external power supply (not shown) is connected to the transparent electrode and the pen-shaped electrode (7). In the case of coloring in a reduced state, the transparent electrode is a negative electrode and a pen. The mold electrode is the positive electrode. For those that develop color in the oxidized state, the reverse potential is applied.

Example 1 CRYSPER (thickness 100 μm) manufactured by Toyobo Co., Ltd. was used as a substrate, and an ITO transparent film was formed on the substrate as an electrode. Color layer (electric color material layer)
As a supporting salt, ethyl viologen, which develops color in a reduced state, was used as a coating solution on the electrode so as to have a thickness of 0.1 μm by using a spin coater, and a methanol solution containing 50% by weight of PMEO was coated thereon. LiClO ₄ is adjusted to ₄ mol% with respect to 1 oxygen of ether, P
What melt | dissolved 0.075g with respect to 1g of MEO was coat | covered so that it might become a thickness (as a polymer solid electrolyte) of 100 micrometers. When a voltage of 3V was applied to the recording sheet material thus prepared, the portion to which the voltage was applied developed color within about 4 seconds. However, in this example, after applying a voltage, bleeding was recognized around the colored portion. Furthermore, the color development in this example uses a plate-shaped stainless steel and has a reverse potential of 3
By applying V, the color was erased within 4 seconds. The repetition of the coloring and the erasing could be executed 120 times. Further, even if the reverse potential was not applied, the color was erased in about 3 minutes with the voltage applied being released. (This is considered to be the decolorization due to natural oxidation by oxygen in the air. To prevent this phenomenon, for example, an oxygen impermeable film can be placed on the layer of the polymer solid electrolyte.)

Example 2 A recording sheet material was prepared in the same manner as in Example 1 (except that butyl viologen was used as the coloring layer and P (MEO-MMA) was used as the solid polymer electrolyte). A voltage of 3 V was applied to the recording sheet material of this example as in Example 1, but the PME
Perhaps because P (MEO-MMA) has a lower conductivity than O,
It took about 40 seconds to develop the color. When the applied voltage was 5 V, the time until color development was shortened within 15 seconds. This coloring and erasing can be repeated at least 200 times. In the case of PMEO (Example 1), even if it was dried sufficiently, the surface was soft and it was considered that color bleeding was caused, but in the case of this example, mechanical strength is high, A sheet-like substance for recording having a sufficiently hard surface was obtained, which probably caused no color bleeding. Further, in this example, the oxidation decolorization due to oxygen in the air was not observed even after 24 hours. That is, the practical improvement of the memory property was observed.

Example 3 A recording sheet material (film) was prepared in the same manner as in Example 2, but the difference from Example 2 was that the thickness of the solid polymer electrolyte layer was reduced to 40 μm. In this example, when the applied voltage was 3 V, the time required for color development was within 10 seconds.

Example 4 A recording film was prepared in the same manner as in Example 2. However, the formation of the polymer solid electrolyte was 5000 r.p.m. p. It was performed using a high speed spin coater of m. As a result, the polymer solid electrolyte layer had a thickness of 20 μm, and the surface uniformity was remarkably superior to that in Example 2. After sufficiently drying, when a response was observed at an applied voltage of 3 V (current value 0.3 μA), color was developed within 6 seconds even faster than in Example 3. In this example, uniform coloring was obtained due to the homogeneity of the solid polymer electrolyte layer, the thinning of the solid electrolyte layer, and the uniformity of the entire recording film, which is considered to be due to the improvement of the adhesiveness between the solid layer and the coloring layer. ..

Example 5 A recording film was prepared in the same manner as in Example 4. However, polyxylyl viologen was used as the coloring layer. In this example, the fixing of the coloring layer on the electrode layer was extremely stable and strong, and the number of times of coloring and decoloring was repeated 200 times or more. Also, uniform color development was observed. However, the time required for color development was 12 seconds, which was slower than that in Example 4, and it is considered that this is because viologen has a larger frequency than alkylviologen and the diffusion rate of the counter anion is decreased.

Example 6 A recording film was prepared in the same manner as in Example 5 except that the anion species of the supporting electrolyte was changed from ClO ₄ ⁻ to Cl ⁻ . The time required for color development was 9 seconds.

(Example 7) P. A recording film was prepared in the same manner as in Example 5 except that B (Brusian blue) was used. In this example,
The polarity of the potential at the time of color development in 6 was reversed.
The time required for color development was within 10 seconds.

Example 8 A recording film was prepared in the same manner as in Example 5 except that a polyethylene terephthalate film (60 μm thick) manufactured by Toyobo Co., Ltd. was used as the substrate instead of the crisper manufactured by Toyobo Co., Ltd. Coloring and decoloring were observed in the same manner as in Example 5, but it was slightly less visible to the naked eye than in Example 5 probably because of the viewing angle dependency.

Example 9 A recording film was prepared in the same manner as in Example 5, except that flexible colored films having conductivity were used as the substrate and the electrodes. In this example, in addition, in order to enhance the contact between the coloring layer and the electrode (electrically conductive film), a polycation (for example,
Poly (N, N-dimethyl-N ', N' dimethylhexamethylene diammonium bromide)) was added and used. In this example, not only the color developability but also the flexibility was excellent.

[0030]

As described above, the film (sheet-like substance) using the electrochromic display element of the present invention can provide a high-resolution display by the application of a local voltage. A large amount of display is possible. This color development can be quickly erased by applying a reverse potential, and a continuously usable recording film that replaces the disposable recording paper can be obtained.

[Brief description of drawings]

FIG. 1 shows a constitutional example of a recording sheet material of the present invention which can be repeatedly used.

[Explanation of symbols]

 1: Substrate 2: Electrode layer 3: Electrochromic material layer 4: Polymer solid electrolyte layer 5 (6): Lead wire from external power supply 7: Pen type electrode

Claims (4)

[Claims] 1. A sheet-like substance which comprises at least a constituent of coating a thin film electrode with a material that develops color by electrical oxidation-reduction, and further coating the polymer solid electrolyte on the material that develops color. A sheet-like substance for recording that can be repeatedly used, characterized in that it partially develops color when a voltage is applied and is erased when a voltage is applied in reverse. 2. The reusable recording sheet material according to claim 1, wherein the material that develops color is one that develops in an electrically oxidized state and that erases in an electrically reduced state. 3. The reusable recording sheet material according to claim 1, wherein the thin film electrode is transparent, and white or colored paper is arranged on the opposite surface of the electrode which covers the material that develops color. .. 4. The reusable recording sheet material according to claim 1, wherein the thin film electrode is a conductive film having conductivity.