KR100684742B1 - Front luminescent type vacuum fluorescent display device - Google Patents

Abstract

The present invention relates to a top-emitting fluorescent display tube capable of minimizing unevenness due to a voltage drop of a conductive material provided on a substrate, and capable of increasing brightness and reducing manpower. A side glass positioned between the side glass to form a closed space; A wiring layer provided on the front substrate and electrically connecting the inside of the fluorescent display tube; A phosphor electrically connected to the wiring to form a predetermined display pattern; A filament installed in a tension state by the support means and emitting heat electrons when the power is applied; A grid electrode for accelerating and blocking hot electrons emitted from the filament; A conductive electrostatic shielding film provided on the rear substrate and for shielding static electricity applied through the substrate, wherein the electrostatic shielding film is made of an opaque material.

Over light emission, fluorescent tube, stain, voltage drop,

Description

Front emitting fluorescent tube {FRONT LUMINESCENT TYPE VACUUM FLUORESCENT DISPLAY DEVICE}

1 is a cross-sectional view of a top-emitting fluorescent display tube according to the prior art.

2 is a cross-sectional view of a top-emitting fluorescent display tube according to the present invention.

The present invention relates to a top-emitting fluorescent display tube for driving a filament by a direct current drive method, and more particularly, it is possible to minimize the unevenness due to the voltage drop of the conductive material provided on the substrate, it is possible to increase the brightness and reduce labor A front emission type fluorescent display tube.

Fluorescent display tubes (VFDs) as self-emissive display elements that selectively collide the hot electrons emitted from the filament with the fluorescent layer of the anode electrode to emit light are classified into general type, top emission type (transmissive type), and double-sided emission type (lamination type) depending on the display area. The filament is divided into an AC driving method, a DC driving method, and a pulse driving method.

The general fluorescent display tube is formed by forming an anode electrode on a rear substrate in a predetermined pattern and printing phosphors thereon so that the emitted light is displayed to the outside through the transmissive front substrate. The anode is formed on the inner surface of the transmissive front substrate in a predetermined pattern and the phosphor is printed thereon so that the emitted light is displayed to the outside through the transmissive front substrate. It is a combination of brothers.

The AC driving method is a method of applying AC as a filament driving voltage, and the DC driving method is a method of applying DC as a filament driving voltage, and the pulse driving method is a filament driving voltage which is considerably higher than a normal rated voltage. DC square wave with chopping (select part of signal) is applied.

Hereinafter, a conventional top emission type fluorescent display tube driven by a DC driving method will be described with reference to FIG. 1.

As shown, the front substrate 102 and the rear substrate 104 are arranged in parallel with each other at regular intervals by the side glass 106.

The inner surface of the front substrate 102 is provided with a wiring layer 108 for electrically connecting the inside of the fluorescent display tube, the wiring layer 108 is provided with a fluorescent layer 110 having a predetermined display pattern, and the fluorescent layer 110 An insulating film 112 is provided on the front substrate 102 except for the portion where () is provided.

The wiring layer 108 is usually provided by photolithography or sputtering of an aluminum film, and a plurality of carbonate-coated filaments 114 are provided in tension by a tension support and a fixed support between the fluorescent layer and the back substrate. A mesh grid 116 is provided between the fluorescent layer 110 and the filament 114 to accelerate or diffuse or block hot electrons emitted from the filament 114.

The back substrate 104 is provided with a conductive indium tin oxide (ITO) coating film 118 for shielding static electricity applied through the substrate 104 by receiving a filament driving voltage, and the ITO coating film 118. The end of the connector is in contact with the tension support.

In this case, the ITO coating layer 118 simultaneously performs a function of diffusing hot electrons by applying an electric force of repulsive force to the hot electrons emitted from the filament 114.

Therefore, when a DC power source for driving the filament 114 is applied, the same voltage as that of the filament is also applied to the ITO coating film 118, so that the static electricity applied from the outside is shielded by the ITO coating film 118 and the hot electrons are caused by the static electricity. The trajectory of can be prevented from changing.

However, as described above, since the ITO forming the coating film is a light transmissive material, in order to prevent the light emitted from the fluorescent layer 110 from being scattered on the rear substrate 104, a conductive light shielding film 120 of an opaque material should be provided.

The conductive light shielding film 120 is usually made of a paste made of graphite, and then printed and baked. Since the graphite material constituting the light shielding film is amorphous in an arrangement of atoms, the end of the connector contacts the light shielding film 120. The end surface damages the membrane surface, resulting in foreign matter.

Therefore, the light blocking film 120 is not generally provided at the portion where the end portion of the connector contacts.

Accordingly, when voltage is applied to the fluorescent layer 110, the filament 114, and the mesh grid 116 through the lead pin 122, the hot electrons emitted from the filament 114 are transferred to the mesh grid 116 and the ITO coating layer. Accelerated and diffused by 118, the fluorescent layer 110 is excited to emit the fluorescent layer, and the emitted light is irradiated to the outside through the front substrate 102 so that an image such as a predetermined letter or symbol is generated. Is implemented.

However, the conventional top-emitting fluorescent display tube constructed as described above has the following problems.

In general, a voltage drop due to a resistance is generated at both end sides of a conductor to which a DC power is applied, and the voltage drop is larger as the specific resistance increases.

However, since ITO and graphite, which constitute the electrostatic shielding film and the light shielding film, are conductive materials having specific resistance units of ㏁m and ㏀m, respectively, both ends of the fluorescent display tube when a DC power source for driving the filament is applied through the connector On the side (where the filament support is installed), a large voltage drop occurs in the film (the electrostatic shielding film and the light shielding film), and the voltage drop increases further as the length of the fluorescent display tube is longer.

Therefore, the electric force of the repulsive force generated in the electrostatic shielding film and the light shielding film becomes weaker as the end of the connector connected to the tension support becomes farther from the contact portion (toward the fixed support side), whereby the tension support is installed in the position where the fixed support is installed There is a problem in that the luminance of the fluorescent layer is lowered compared to the position, thereby causing unevenness.                         

In addition, since the electrostatic shielding film is formed of a light-transmissive ITO coating film, there is a process problem in that an opaque light-shielding film must be separately installed.

In addition, it is not easy to check whether the film is coated well because the ITO coating film is transparent.

Accordingly, an object of the present invention is to provide a top-emitting fluorescent display tube capable of minimizing unevenness due to a voltage drop of a conductive material provided on a substrate and increasing luminance and reducing man-hours.

In order to achieve the above object, the present invention proposes a top-emitting fluorescent display tube composed of an electrostatic shielding film using an opaque material having a significantly lower specific resistance than ITO and graphite.

Hereinafter, a top-emitting fluorescent display tube according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view of a top-emitting fluorescent display tube according to the present invention, wherein an inner surface of the front substrate 12 is provided with a wiring layer 18 formed by photolithography or sputtering an aluminum film, and the wiring layer 18 is provided with a wiring layer 18. The fluorescent layer 20 which forms a display pattern, and the insulating film 22 which prevents unnecessary energization between wirings are provided.

Tension supports and fixed supports for supporting a plurality of filaments 24 coated with carbonate at predetermined heights are provided at both sides in the longitudinal direction of the front substrate 12, respectively, and the fluorescent layer 20 and the filament 24 are provided. The well-known mesh grid 26 is provided in between.

On the other hand, a conductive electrostatic shielding film 28 for shielding static electricity applied through the substrate 14 is provided on the rear substrate 14 assembled by the side glass 16 in a position facing the front substrate 12. In the present invention, the shielding film 28 is made of aluminum (Al) or silver (Ag), which is a wiring forming material.

The aluminum (Al) and silver (Ag) are materials having resistivity values of 2.8 × 10 ⁻⁸ mm and 1.6 × 10 ⁻⁸ mm, respectively, at 20 ° C., and are 4.2 × 10 ⁻³ mm and 1.0 × 10 ⁻³ mm, respectively. It has a significantly lower resistivity compared to ITO and graphite having a resistivity.

In addition, since the aluminum (Al) and silver (Ag) are opaque materials, there is no need to provide a separate conductive light shielding film to the electrostatic shielding film, and since the aluminum and the silver (Ag) are crystalline, the surface of the film is not damaged when the ends of the connector are in contact.

Herein, the aluminum may be provided by a thin film process such as sputtering, and the silver may be provided by a thick film process such as printing. The electrostatic shielding film 28 thus provided may provide an electric force of repulsive force to hot electrons emitted from the filament. The effect of diffusing hot electrons by acting is also performed at the same time.

Then, in order to apply the filament driving voltage to the electrostatic shielding film 28, the film 28 is in contact with an end of a connector electrically connected with a tension support for supporting the filament in a tensioned state.

Accordingly, when a direct current power source for driving the filament is applied to the electrostatic shielding film 28, the film 28 acts to shield the static electricity applied through the substrate 14 from the outside, so that It is possible to prevent the trajectory from changing.

In addition, hot electrons emitted from the filament 24 during the above-described action are diffused by the electric force of the repulsive force generated in the electrostatic shielding film 28 to impinge on the fluorescent layer 20 to emit the fluorescent layer. In the film 28, a small amount of voltage drop occurs as compared with the conventional electrostatic shielding film 118 of FIG.

Therefore, since the amount of hot electrons reaching the fluorescent layer 20 is increased, the luminance of the fluorescent layer is improved.

In addition, since the voltage drop is small, staining is minimized at one side of the fluorescent display tube, that is, the position where the fixed support is installed.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to

As described above, according to the fluorescent display tube of the present invention, the aluminum (Al) or silver (Ag) constituting the electrostatic shielding film has a very low resistivity compared to ITO and graphite due to the properties of the material, so that the voltage drop of the film Reduced luminance and spots are minimized.                     

In addition, since the material is opaque, it is not necessary to provide a conventional conductive light shielding film for preventing the light emitted from the fluorescent layer from being scattered, and it is possible to reduce labor and visually easily whether the coating of the film is good. Can be identified.

In addition, since the material is crystalline, there is no effect of generating foreign matters due to damage of the membrane surface by the end of the connector.

Claims (3)

A side glass positioned between the front substrate and the rear substrate and these substrates to form a closed space; A wiring layer provided on the front substrate and electrically connecting the inside of the fluorescent display tube; A phosphor electrically connected to the wiring to form a predetermined display pattern; A filament installed in a tension state by the support means and emitting heat electrons when the power is applied; A grid electrode for accelerating and blocking hot electrons emitted from the filament; A conductive electrostatic shielding film provided on the rear substrate to shield static electricity applied through the substrate; And the electrostatic shielding film is made of an opaque material containing aluminum (Al) or silver (Ag). delete delete

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