JPH01304420A - Information display device - Google Patents

Abstract

PURPOSE:To obtain the device having a voice output function as well by providing an image carrying film having a high-polymer layer which is made transparent/opaque by heating and a piezoelectric sheet. CONSTITUTION:The information display device 11 is constituted by sticking the image carrying film 1 and the piezoelectric sheet 2 consisting of a PZT composite sheet. The high-polymer material used for the high-polymer layer is a material exhibiting a thermotropic liquid crystal property and, for example, a side chain type high-polymer liquid crystal formed by consisting the same of a methacrylic acid polymer or siloxane polymer as the main chain and adding a low-molecular liquid crystal in a pendent state thereto, or a main chain type high-polymer liquid crystal of a polyester system or polyamide system, etc., are used. For example, the rewriting of the information display device is possible if the high-polymer liquid crystal expressed by the constitutional formula I is used. This high-polymer liquid crystal is dissolved by dichloroethane and the soln. prepd. in such a manner is coated by an applicator on a transparent polyester base plate subjected to cleaning with alcohol; thereafter, the base plate is rested for 10 minutes in 95 deg.C atmosphere, by which the white scattering film is obtd.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to an information display device capable of displaying an old-fashioned display and having a voice output.

[Prior art] Conventionally, films in which piezoelectric ceramics are dispersed in organic resin binder, polyvinylidene fluoride (PVDF),
It is known that this product is applied as a thin speaker by applying a voltage to a piezoelectric film such as PVDF/polyvinyl acetate JL (PVA) copolymer, and its practical use in advertising posters, interior panels, etc. has also begun. ing. ("Synthetic Resin J vof!,: 12. NoJ, p. 8 (198
6), published by the Japan Synthetic Resin Technology Association)
Photo, lI! ! Display objects such as pictures are integrated with the thin speaker. Therefore, the methods of replacing the display that is already in use with another display are to replace the other display with another panel that is integrated with a thin speaker, or to replace the display that is already in use. Since it was necessary to attach another display to the panel or to print over it, there were problems such as the panel being disposable and the sound quality decreasing.

On the other hand, displays using TN (twisted nematic) liquid crystal materials have been put into practical use as wall-type displays because they can be made thinner, and the liquid crystal material is sealed in a glass cell with a controlled thickness. In particular, there are disadvantages of increased manufacturing processes and higher costs.

Furthermore, even in the case of 0 old images using liquid crystal materials as described above, there is a drawback that pixel voltage must always be supplied.

The present invention has been made in order to improve the shortcomings of the prior art, and aims to provide an information display device that allows the display contents to be rewritten and changed, and also has an audio output function. This is the purpose.

[Means for Solving the Problem] and [Operation] That is, the present invention is composed of an image-bearing film and a piezoelectric sheet or piezoelectric film having at least a polymer layer that becomes transparent or opaque when heated. This is a characteristic information display device.

The present invention will be explained in detail below.

The image-bearing film used in the present invention is a polymer made by coating or laminating a polymer material that becomes transparent or opaque when heated on a plastic substrate such as polyethylene terephthalate, polycarbonate, cellulose triacetate, or polymethyl methacrylate. A structure formed by laminating molecular layers is used. For the above-mentioned ζ bodies, thin glass can also be used depending on the case.

The piezoelectric sheet or piezoelectric film used in the present invention is not particularly limited, and any commonly used piezoelectric sheet or piezoelectric film may be used, such as a ceramic composite sheet, a fluoropolymer film, a cyanide polymer Examples include molecular films. These are generally several hundred to 100O
Piezoelectricity is developed by heating and holding the material at a temperature for polarization treatment in IB to which a direct current electric field with a strength of KV/cm is applied, and then allowing it to cool to room temperature.

The information display device of the present invention may be constructed by laminating the image-bearing film and a piezoelectric sheet or a piezoelectric film, or may further include:
Coating or laminating the polymeric material 4 directly onto the piezoelectric sheet or film is also a component rotation.

Next, the information display device of the present invention will be explained based on the drawings.

FIG. 1(a) is a front view showing a typical example of the information display device 11 of the present invention, and FIG. 1(b) is a side view thereof, showing an image-bearing film 1 and PZT (lead titanate-lead zirconate). It is made by laminating piezoelectric sheets 2 made of composite sheets. FIG. 2 is a side view showing another example of the information display device of the present invention, in which a transparent piezoelectric sheet 2 made of vinylidene cyanide/vinyl acetate copolymer is laminated to an image-bearing film l. . In Figure 2, by placing the piezoelectric sheet 2 in the front, the sound quality as a speaker can be improved.
This is more advantageous because it prevents a decrease in tone.

Writing or rewriting an image on the information display device of the present invention is performed, for example, by scanning the thermal head 3 in the scanning direction A, as shown in FIGS. 3(a), 3(b) and 4. Something will happen. (However, the moving device for the thermal head is not shown):jS5 Figures (a) to (d) are examples in which a piezoelectric sheet or piezoelectric film is partially used in the information display device 11 in Figure 1 or Figure 2. Figure 5 (a) and (b)
.

In (C), it is also possible to apply separate audio signals to each part.

Further, in the case of the type in which the piezoelectric sheet or piezoelectric film is operated by being bent, the image-bearing film is also used in a bent manner as shown in FIG.

The polymer material used for the polymer layer in the present invention is a material exhibiting thermotropic liquid crystal properties, such as a side chain type polymer liquid crystal with a main chain of methacrylic acid polymer, siloxane polymer, etc. and low molecular liquid crystals added in a pendant form; Further, polyester-based or polyamide-based main chain polymer liquid crystals may be used.

As one specific example of the above-mentioned polymer liquid crystal, when a polymer liquid crystal shown in the following structural formula (I) is used,
The fact that the information display device can be rewritten will be explained.

MW = 18,000 The polymer liquid crystal was dissolved in dichloroethane, and this was applied using an applicator onto a polyester transparent substrate that had been washed with alcohol. Thereafter, when it was left in an atmosphere at 95°C for 10 minutes, a white scattering film was formed. This film thickness is determined by the concentration of polymer liquid crystal before coating.
In the case of 0 wt%, a product with a strength of just over 10% was obtained.

When the white sheet obtained above was scanned with a thermal head, the transparent portion was fixed according to the character 1 graphic pattern. When this sheet was introduced onto a black backclarant having an optical density of 1.2, a clear display of black on a white background was obtained.

Next, the entire surface of the sheet on which the above pattern was recorded was
When heated to 0'C and then kept at about 90C for a few seconds, the entire surface returned to its original white scattering state2.It remained stable even if returned to room temperature, and recording and display could be performed again. Ta.

The above development is carried out in a film state below the glass transition point at which the polymeric liquid crystal maintains a stable memory state, at a liquid crystal film state 7.1 at which it can maintain a substantially optical scattering state of 7.1, and at higher temperatures. It can be controlled because it can take at least three isotropic film states in which the molecules are arranged in an isotropic manner.

In addition to those shown in the above structural formula, a large number of polymeric liquid crystals that can be used in the final product can be used. Several other examples of polymeric liquid crystals are listed below, but the invention is not limited to these.

shi1ass i佼ti41LNJ
lso.

711・ (IV) 140°C196°C Glass-liquid crystal phase (Sm)-rso.

In addition, as a solvent for coating and forming the polymer liquid crystal, in addition to dichloroethane, DMF, cyclohexane, etc., tetrahydrofuran (TIIF), acetone, ethanol, other polar or non-polar solvents, or a mixed solvent thereof may be used. It goes without saying that these can be selected depending on factors such as solubility with the polymer liquid crystal used, the material of the substrate to which it is coated, or wettability with the surface layer provided on the surface of the substrate, film formability, etc. do not have.

Next, the principle process for displaying an image by providing a polymeric liquid crystal phase on a polyethylene terephthalate substrate will be explained using FIG.

In FIG. 7, the scattering state, which is the background or the state before aging yE;, is the state indicated by ■ in the figure. This is heated to T2 (T,
,. = isotropic state transition temperature) After heating to a temperature higher than (2) a, and then rapidly cooling, the light transmitting state, which is almost the same as the isotropic state, is fixed, as shown in (2) in Fig. 1. This rapid cooling state does not require any particular cooling means, and it is sufficient to allow the substrate to naturally radiate heat into the air. This isotropic state is stable at room temperature or room temperature below T+ (Tg = glass transition temperature),
In other words, it is in a stable state as a single image memory.

On the other hand, as shown in ■a, when the liquid crystal temperature is heated to 12 or more and then held for one to several seconds between the liquid crystal temperature T and T2, as shown in ■b, the scattering intensity increases again during this holding time, and at room temperature The original scattering state (2) is restored again, and this state is stably maintained below T.

Also, as shown by ■ in the figure, 1 between the liquid crystal temperature T and T2
For example, if it is held for a period of 10 milliseconds to 1 second, that part can be held at room temperature as a transparent 7g, and it can also be used for gradation expression. .

In other words, in this example, the transmittance or scattering intensity can be controlled by how long the liquid crystal temperature is maintained at room temperature after heating to an isotropic state. It is possible to maintain it stably. Furthermore, in the case of "bipods", the temperature to return to the scattering state is faster or closer to T2 within the liquid crystal temperature, and if the temperature is left at the liquid crystal temperature for a relatively long time, it is necessary to not heat it to the isotropic state once. , it is possible to return to the scattering state (■) regardless of the previous state.

[Example] Hereinafter, the present invention will be explained in more detail with reference to Examples.

Example 1 Thickness 1 with transparent conductive layer of ITO provided as heat generating layer
A polymeric liquid crystal having the following structural formula (I) was coated on a polyester film of 004++++ to a thickness of 5 to 8P11 to prepare an image-bearing film.

This image-bearing film was bonded to a polarized PZT-based composite piezoelectric sheet having a thickness of 5 mm and having electrodes on both sides. The thermal head shown in FIG. 3 was scanned on the panel thus prepared in the following manner, and it was confirmed that rewritten display could be performed.

The temperature of the polymer liquid crystal layer was raised to about 60° C. by applying electricity to the 170 layer, fE, and the thermal head was scanned to bring the surface temperature of the polymer liquid crystal layer to BooC, so that the entire surface was in a white scattering state.

Next, the energization of the 170th layer was stopped, and f9 scanning was performed using a 100° C. thermal head to form a first display screen.

Next, in the same manner as above, the entire surface was covered with a white scattering layer, and the first display was erased. Then, the second display is performed in the same way,
When a second display screen was formed, there was no difference in contrast, etc. from the first display screen.

Also, 1st. Good sound was obtained by applying an acoustic signal to the piezoelectric sheet in the second display state.

Example 2 On one side of a polarized vinylidene cyanide/vinyl acetate copolymer film having electrodes on both sides and having a thickness of 30 gm,
As an electrical insulating layer, a heat-resistant ultraviolet-curable acrylic paint was applied to a thickness of approximately 5 mm and cured. On the transparent piezoelectric film on which 170 layers were formed by dip coating, a laminated film having a polymeric liquid crystal layer was formed in the same manner as in Example 1 to produce an information display device having the structure shown in FIG. 2.

A black film was laminated on the back side of the obtained information display device to improve contrast, and from the piezoelectric film side,
When old scanning was performed using a thermal head in the same manner as in Example 1, by increasing the amount of thermal energy by about 30% compared to Example 1, it was possible to perform rewriting scanning similar to that in Embodiment 1. Since this piezoelectric film is a curved type, it was used in the shape shown in FIG.

Further, as in the first embodiment, the first. By applying an acoustic signal to the piezoelectric sheet in the second display state.

Good audio was obtained.

Note that one display screen could be backlit with a fluorescent lamp or an EL (electroluminescent) panel T instead of the above-mentioned black film, and visibility could be improved by transmitted light.

[Effects of invention As explained above, the information display device of the present invention is provided.

The displayed content can be easily rewritten and changed, and audio information and music can be provided, increasing the value of use as an information board with improved immediacy and an advertising panel with high advertising effectiveness. have an effect.

[Brief explanation of the drawing]

FIG. 1(a) is a front view showing a typical example of the information display device of the present invention, FIG. 1(b) is a side view thereof, FIG. 2 is a side view showing another example of the information display device, and FIG. Figure (a). (b) and FIG. 4 are explanatory views showing how images are written by an old replacement thermal head, and FIGS. 5(a) to (d) are explanatory views showing still other examples of the information display device of the present invention. ,
FIG. 6 is a perspective view showing a curved information display device and FIG.
The figure is a graph illustrating the image forming process. ■...Carrier film 2...Piezoelectric sheet 3...Thermal head 11...Information display device

Claims (2)

[Claims] (1) An information display device comprising an image-bearing film having at least a polymer layer that becomes transparent or opaque when heated, and a piezoelectric sheet or a piezoelectric film. (2) The information display device according to claim 1, wherein the polymer layer is a polymer liquid crystal layer.