JPH08160399A - Driving power source for external charging type liquid crystal display element - Google Patents

Abstract

PURPOSE: To provide a driving power source device simple in structure, low at manufacturing cost, superior in safety, small in power consumption, to be used for an external charging type liquid crystal display element in which liquid crystal dispersion polymer layers in which transparent high electric resistance and liquid crystal are finely dispersed in a polymer matrix are successively laminated on a conductive layer. CONSTITUTION: This device is constituted of a blocking oscillation circuit constituted of a DC low voltage power source 2, a power source switch 3, a transistor 5 for oscillation and an oscillation transformer 9 for boosting low voltage generated by the DC low voltage power source 2, a rectifying diode 10 for rectifying voltage generated by the blocking oscillation circuit, a smoothing capacitor 11 for charging voltage after rectifying and smoothing output voltage, and resistors 12-15 connected between the smoothing capacitor 11 and output terminals 16, 18 and regulate an output current value to 5mA or less.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving power supply device for an external charging type liquid crystal display element. Specifically, displaying or erasing an image using a liquid crystal dispersed polymer layer that selectively transmits or scatters light by utilizing the electro-optic effect that changes the light scattering state of liquid crystal depending on the presence or absence of an electrostatic field. The present invention relates to a drive power supply device for charging an electrostatic charge on the surface of an externally chargeable liquid crystal display element, which can be used.

[0002]

2. Description of the Related Art Heretofore, many proposals have been made for a liquid crystal display element utilizing the electro-optical effect of liquid crystal and a liquid crystal display device using the liquid crystal display element. Among them, a liquid crystal display device using a liquid crystal dispersion polymer layer in which liquid crystals are finely dispersed in a polymer matrix does not require a polarizing plate or an alignment film, and thus a bright and large screen can be obtained relatively easily, and thus has been attracting attention in recent years. ing.

In Japanese Patent Publication No. 3-52843, etc.,
A liquid crystal light control panel has been proposed in which a liquid crystal dispersed polymer layer is sandwiched between transparent electrodes. In this liquid crystal light control panel, nematic liquid crystal or the like is finely dispersed in a water-soluble polymer aqueous solution such as polyvinyl alcohol and dried to form a liquid crystal dispersion polymer layer. Regarding the driving method, after sandwiching the liquid crystal dispersed polymer layer between two transparent electrodes, an alternating voltage is applied between the electrodes by an alternating voltage power source to align the liquid crystal molecules in the liquid crystal dispersed polymer layer in the direction of the electric field. Let This driving method is not limited to this patent, and is a method that is almost common to conventional liquid crystal display elements.

The applicant of the present invention also discloses, according to the publication of Japanese Patent Application Laid-Open No. 5-224182, a transparent high electric resistance layer, a liquid crystal-dispersed polymer layer in which liquid crystal is finely dispersed in a polymer matrix, according to the publication of JP-A-5-224182. And an "externally charged liquid crystal display device" in which transparent insulating layers are sequentially stacked. Further, using such a liquid crystal display element, a writing means for applying an electrostatic charge from the outside onto the surface of the transparent insulator layer, and an erasing means for removing the electrostatic charge on the surface,
A power supply for generating a surface potential on the surface is provided, and an electrostatic charge is applied to and removed from the surface by the writing unit and the erasing unit, whereby an image can be easily written / erased on the screen repeatedly. A "handwritten liquid crystal board set" was proposed in Japanese Patent Application Laid-Open No. 5-281530.

[0005]

In the above external charge type liquid crystal display element, a transparent high electric resistance layer having a high volume resistivity is provided in its constitution, and further the volume resistivity of the liquid crystal dispersed polymer layer is increased. As a result, the electric field applied between the conductive layer and the surface of the transparent insulator layer of the present liquid crystal display element is maintained without flowing as a current, thereby maintaining the alignment of the liquid crystal molecules in the liquid crystal dispersed polymer layer in the electric field direction. You can do it. However, on the other hand, it is necessary to apply a relatively high DC voltage in order to align the liquid crystal molecules and display them on the liquid crystal display element. Therefore, as a drive power supply device for operating the externally charged liquid crystal display element of the present applicants, in the drive power supply device utilizing the AC low voltage for the conventional liquid crystal display element, a continuous writing line is formed on the display screen. I can't get it.

Further, the present inventors have proposed the above-mentioned "handwritten liquid crystal board set" by using this externally charged liquid crystal display element. The "handwritten liquid crystal board set" is to be offered to the market as a toy. Therefore, the conventional general DC voltage power supply device was not satisfied by the present inventors due to its size, cost, safety and the like.
Also, due to the nature of the toy, dry batteries are preferable as the primary power source of the DC voltage power supply device because of their easy availability and handling, but in order to extend the life of the dry batteries and reduce the frequency of replacement, the DC voltage power supply Power consumption should be as low as possible. The present inventors are obliged to obtain a drive power supply device that outputs a direct current voltage that has a new simple structure, is inexpensive, excels in safety as a toy, and consumes less power. A new driving power supply device for an externally charged liquid crystal display element satisfying the present inventors can be obtained, and the present invention has been achieved.

An object of the present invention is to provide a driving power supply device which can be used in an externally charged liquid crystal display device having high volume resistivity and image memory property, has a simple structure, is inexpensive, is excellent in safety and consumes less power. Is to get.

[0008]

The present invention provides at least the following:
A transparent high electric resistance layer and a liquid crystal-dispersed polymer layer in which a liquid crystal is finely dispersed in a polymer matrix are sequentially laminated on a conductive layer to charge an electrostatic charge on the surface of an externally charged liquid crystal display device. In a driving power supply device in which an output terminal is connected to the conductive layer, an output terminal electrically having the same electric potential as one output terminal is electrically connected to an erasing means, and the other output terminal is electrically connected to a writing means. At least a DC low voltage power supply, a power switch, and for boosting the low voltage generated by the DC low voltage power supply to 50 to 2000V,
A blocking oscillating circuit including an oscillating transistor and a boosting oscillating transformer, a rectifying diode for rectifying the voltage generated by the blocking oscillating circuit, and a voltage after the rectification are charged to smooth an output voltage. The external charging type liquid crystal display device driving power supply device comprises a smoothing capacitor for controlling the output current and a resistor connected between the smoothing capacitor and the output terminal to regulate the output current value to 5 mA or less.

Furthermore, the externally charged liquid crystal display element drive power supply device is characterized in that the current flowing through the primary winding side of the blocking oscillator circuit is 10 mA or less.

The external charge type liquid crystal display element in the present invention is disclosed in Japanese Patent Application Laid-Open No. 5-224182 as described above, and the conductive layer is either transparent or opaque, which will be briefly described here. However, a material having a surface resistance of 10 ⁷ Ω / □ or less is used. metal,
It can be obtained by making the surface or the whole of a metal alloy plate foil, plastic, or glass substrate conductive with a conductive material such as metal, metal alloy, metal oxide, graphite, or conductive polymer.

The high electric resistance layer means a layer having a volume resistivity of 10 ¹³ Ω · cm or more at a temperature of 20 ° C. and a relative humidity of 90%, and is made of various polymer films as an adhesive,
Laminating with adhesives, applying various polymer solutions,
It can be obtained by drying.

As the liquid crystal, a nematic liquid crystal having a positive dielectric anisotropy is used.

In the driving power supply device used for the external charging type liquid crystal display element composed of each of the above materials, a dry battery, a solar battery or the like can be used as the low voltage power supply, but it is easily available and easy to handle. 1.5 for ease of use
V dry cells are preferred.

The oscillating transistor, the boosting oscillating transformer and the rectifying diode are generally provided on the market and are not special ones.

In the boosting oscillating transformer, the number of turns on the primary side and the number of turns on the secondary side are determined from the relationship between the input voltage and the output voltage to be obtained.

As the smoothing capacitor, a capacitor having a capacity corresponding to the rectified voltage is used. When this drive power supply is used for a handwritten liquid crystal board set, one terminal of the drive power supply is connected to the conductive layer of the external charge type liquid crystal display element, and the other terminal is connected to the writing means made of a conductive material. hand,
Writing is performed by charging the surface of the liquid crystal display element with a writing means while turning on the switch, and at this time, when writing is performed at a high speed, stable voltage is supplied by the smoothing capacitor. You can get handwriting.

It is generally said that the current value at which no electric shock occurs when a current flows through the human body is 5 mA or less. Therefore, a resistor is connected in order to regulate the output current from the smoothing capacitor to 5 mA or less, and the resistor is preferably in the range of 200 KΩ to 100 MΩ in view of the relationship with each member described above.

[0018]

In the drive power supply device of the present invention, when the power switch is turned on, a current flows from the DC low voltage power supply to the primary winding connected to the collector of the oscillation transistor, and the current is excited in the winding connected to the base. As a result, the current flowing through the collector increases. At some point, the collector-emitter saturation voltage increases sharply and the voltage across the primary winding connected to the collector decreases. As a result, the oscillation transistor is switched off. At this time, a current is excited in the secondary winding by the energy stored in the boosting oscillation transformer (core). The current excited in the secondary winding causes current to be excited in the winding connected to the base again, and the oscillation transistor is turned on.
Current flows in the primary winding, which is switched to N and connected to the collector.

Oscillation occurs due to the repetition of operations (1) to (3), and a pulsed voltage proportional to the number of turns of the primary winding and the secondary winding is generated in the secondary winding. This pulsed voltage is half-wave rectified by the diode and stored in the capacitor.

One output terminal of the capacitor is connected via a resistor to the conductive layer of the externally charged liquid crystal display element and the erasing means, and the other output terminal is connected to the writing means via a resistor to connect to the external charging type. Writing and erasing are performed on the screen of the liquid crystal display element by using the writing means and the erasing means,
Due to the interposition of the resistor, the current value is regulated to 5 mA or less even when the output current flows through the human body.

[0021]

Embodiments of the present invention will be described below with reference to the drawings.

The externally charged liquid crystal display element drive power supply device 1 of the present embodiment is constructed as shown by the circuit diagram within the dotted line in FIG. 1, which is a schematic diagram showing its circuit diagram and usage state. In the figure, 2 is a direct current low voltage power source composed of a 1.5 V alkaline dry battery. 3 is a power switch. Reference numeral 4 is a smoothing capacitor of 47 μF. 5
Is a transistor for oscillation. 6 is 56 KΩ and 7
Is a resistance of 560Ω. Reference numeral 8 is a 0.22 μF oscillation capacitor. Reference numeral 9 is a boosting oscillating transformer having a winding ratio of about 1: 380. A blocking oscillator circuit is constituted by 4-9. 10 is a rectifying diode, 11 is 330p
This is an F smoothing capacitor. 2-11, DC-DC
It constitutes a converter circuit. 12, 13, 14 and 15 are 5.1 MΩ current value regulating resistors. 1
6, 17 and 18 are output terminals.

While the power switch 3 was turned on, the voltage between the output terminals 16 and 18 was measured by connecting the high voltage probe 9014 to the digital high tester 3231-01 of Hioki Electric Co., Ltd., and the output voltage was 560V. It was

Next, as shown in FIG. 1, a transparent high electric resistance layer, a liquid crystal dispersed polymer layer in which liquid crystal is finely dispersed in a polymer matrix, and a transparent insulator layer are sequentially laminated on the conductive layer. One output terminal 18 of the driving power supply device 1 was connected to the conductive layer of the external charge type liquid crystal display element 19.
Further, an electrically conductive sponge having a volume resistivity of 4 × 10 ³ Ω · cm at an ambient temperature of 23 ° C. and 50% RH was connected to the output terminal 17 having the same electric potential as one of the output terminals 18 as an erasing means 20. . Further, as the writing means 21 at the other output terminal 16 of the driving power supply device 1, 50% R at an air temperature of 23 ° C.
At H, a conductive sponge having a volume resistivity of 4 × 10 ⁴ Ω · cm was connected.

While the power switch 3 of the driving power supply 1 is turned on, the external charging type liquid crystal display element 19 is written by the writing means 21.
Was written on the surface of (i.e., on the transparent insulator layer).
By turning on the power switch 3, the output terminal 1
Since a DC voltage of 560 V is generated between the output terminal 8 and the output terminal 16 (between the conductive layer and the writing means 21), the writing means 21
By writing on the surface of the liquid crystal display element, an electric field was applied between the surface of the liquid crystal display element and the conductive layer.
The liquid crystal molecules in the liquid crystal dispersed polymer layer were oriented in the direction of the electric field, and a difference in the contrast of the light transmitting or scattering portion into the liquid crystal board was generated, and a handwritten image could be displayed.

When the erasing means 20 was used to erase the written image, it was erased cleanly. Since the conductive layer and the erasing means 20 have the same electric potential, the electric field applied between the surface of the liquid crystal display element and the conductive layer is neutralized and removed, and the alignment of the liquid crystal molecules in the liquid crystal dispersed polymer layer is improved. It disappears and the written image can be erased.

Also, with the power switch 3 turned on,
The conductive layer and the writing means 21 were brought into contact with the human body at the same time, but there was no electric shock. When the current flowing through the output terminal 16 was measured by the digital high tester 3231-01 described above, the current value was 1 μA.

Further, the current flowing through the primary winding side of the step-up transformer 9 with the power switch 3 kept ON was measured by using the digital high tester 3231-01, and it was 3 mA. Also, turn on the power switch 3.
The external charge type liquid crystal display element 19 has a small power consumption even if left in the above state for 300 hours.
I was able to display the written image on.

[0029]

Since the driving power supply for external charge type liquid crystal display device of the present invention has the structure as described above, it can be manufactured relatively easily and inexpensively.

Further, between the main capacitor and the output terminal, 20
Since a limiting resistance of 0 KΩ to 100 MΩ is connected and the output current value is regulated to 5 mA or less, there is no electric shock even if a human body directly contacts the output terminals.

The current flowing on the primary winding side of the oscillator circuit is 10
Since it is regulated to mA or less, power consumption during continuous oscillation is small, and particularly when a dry battery is used as a low voltage power source, it is not necessary to replace the dry battery for a long period of time.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a drive power supply device for an externally charged liquid crystal display element according to the present invention, and a schematic diagram showing its use state.

[Explanation of symbols]

 1 External charge type liquid crystal display element driving power supply device 2 DC low voltage power supply 3 Power supply switch 5 Oscillation transistor 9 Boosting oscillation transformer 10 Rectifying diode 11 Smoothing capacitor 12, 13, 14, 15 Resistance

Claims (2)

[Claims] 1. An electrostatic charge is applied to at least the surface of an externally charged liquid crystal display element, which is formed by sequentially laminating a transparent high electric resistance layer and a liquid crystal dispersed polymer layer in which a liquid crystal is finely dispersed in a polymer matrix on a conductive layer. One of the output terminals for charging is electrically connected to the conductive layer, one of the output terminals is electrically connected to the erasing means, and the other is electrically connected to the writing means. In the drive power supply device connected to, at least a DC low voltage power supply, a power switch, and a low voltage generated by the DC low voltage power supply are 50 to 2
000V, a blocking oscillation circuit composed of an oscillation transistor and a boosting oscillation transformer, a rectifying diode for rectifying the voltage generated by the blocking oscillation circuit, and a voltage after the rectification. And a drive for an externally charged liquid crystal display element, which comprises a smoothing capacitor for smoothing the output voltage, and a resistor connected between the smoothing capacitor and the output terminal to regulate the output current value to 5 mA or less. Power supply. 2. The drive power supply device for an external charging type liquid crystal display device according to claim 1, wherein the current flowing through the primary winding side of the blocking oscillator circuit is 10 mA or less.