JPS62262341A - Discharge luminous element - Google Patents

Abstract

PURPOSE:To obtain a discharge luminous element with a high resolution and available to a write light source for a shortwave range of such as ultraviolet rays, by arranging the second electrode group crossing oblique to the first electrode group so as to line up the perpendiculars passing the crossing points of the first and the second electrode groups, and crossing at right angles to the first elctrode group, at equal intervals horizontally. CONSTITUTION:In order to line up perpendiculars passing the crossing points of a scanning electrode group 3 and a signal electrode group 5, and crossing at right angles to the scanning electrode group 3, at equal intervals horizontally, the signal electrode group 5 is arranged to cross oblique to the scanning electrode group 3. The perpendiculars crossing at right angles to the scanning electrode group 3 are arranged to line up at equal intervals B to 16 mm, for example. In such a way it can be made into an array light source with a high resolution equivalently. To specific electrodes of the scanning electrode group 3 and the signal electrode group 5 of the discharge luminous element, rectangular wave voltage of about 100 KHz frequency and 300 V voltage between electrodes is applied in order at 1/8 duty, and a sensitive paper is moved in the direction about square to the scanning electrode group 3, so that the light including ultraviolet rays of different wavelength ranges is radiated on the paper in order.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a discharge light emitting device using plasma, and more particularly to a discharge light emitting device used as a writing light source in color hard copy technology.

[Summary of Disclosure] Book 191 Details: IJ and drawings show that in a discharge light emitting device using plasma, a scanning electrode group and a signal electrode group are diagonally crossed,
By arranging the stone lines perpendicular to the scanning electrode group so that they are lined up at equal intervals, and by providing a group of light guide paths at positions corresponding to the intersections of both electrode groups, it is possible to increase resolution. It is something.

[Prior Art] In recent years, printers that can form color images,
So-called color hard copy technology such as copying machines is becoming increasingly important in various fields. This type of color hard copy technology is based on electronic r-photography technology! , k, thermal transfer technology, etc.

However, since electrophotography technology requires a complicated process for image formation, it is difficult to create a compact device with a simple structure and low cost, and thermal transfer technology requires a complicated process to form an image. Because it requires an image forming process, it was difficult to obtain high-resolution images.Also, since all of these technologies superimpose images of the three primary colors, it is easy for each image to be misaligned, and the image forming time is tripled. Recently, it has been possible to obtain some materials that react only to light in one specific wavelength range and do not react to light in other wavelength ranges. An image forming method using these materials has been proposed.This method uses materials that react and harden with light in different wavelength ranges, and methods for making these materials develop different colors. The dyes are mixed and encapsulated and applied to paper or the like through a binder to form a photosensitive member. Image information containing light in a plurality of different wavelength ranges is irradiated onto this photosensitive member, and then an image is formed by applying pressure, etc. It forms the

According to this method, since the image is sharpened by a series of light irradiations, it is possible to easily obtain a high-quality image without color shift.

[Problems to be Solved by the Invention] The penetrating light sources in such an image forming method include orange light emission using neon gas or ultraviolet rays in the vacuum ultraviolet region caused by discharge of a helium-xenon mixed gas, and ultraviolet rays in the vacuum ultraviolet region. The use of gas discharge display devices that utilize light emission from phosphors is being considered. However, the resolution of this gas discharge display device is 2 to 4 lines/ff.
1a1, and it was difficult to achieve the resolution of about 8 to 16 lines/111 required for the above-mentioned hard copy apparatus in terms of discharge control. Furthermore, these devices mainly use ultraviolet rays in the vacuum ultraviolet region within the cell container, and because the attenuation is significant in the air, it has been difficult to irradiate the photosensitive member with the light in the air.

The present invention eliminates the drawbacks of the conventional example, has high resolution,
The object of the present invention is to provide a discharge light emitting device that can be used as a writing light source in a short wavelength region such as ultraviolet light.

[Means for Solving the Problems 1] As shown in FIGS. 1 and 2 of the embodiment drawings, the present invention provides a cell comprising a substrate 2, a face plate 8, and insulating members such as a seal member 9. This is a discharge light emitting element in which a discharge gas 7 is sealed in a container and discharge is caused at selected intersections of a scanning electrode group 3 and a signal electrode group 5 that intersect with each other, the scanning electrode group 3 and the signal electrode group 5 The signal electrode group 5 is arranged to cross diagonally with respect to the scanning electrode group 3 so that the perpendicular lines passing through each intersection of the scanning electrode group 3 and perpendicular to the scanning electrode group 3 are lined up at equal intervals in the horizontal direction. , and, as shown in FIG. 3, on the face plate 8, which is one of the insulating members,
This is a discharge light emitting device characterized in that a plurality of light guide paths 21 are provided corresponding to each intersection of both electrode groups.

[Function] In the discharge light emitting device according to the present invention, as shown in FIG. 1, the intersections of the electrode groups are continuous in the diagonal direction fi! , so that the interval between each intersection of the electrode group can be increased, and even if the number of scanning electrodes is increased, discharge control can be performed easily. In addition, the perpendicular lines passing through each intersection of the electrode group are arranged at equal intervals, forming an equivalent 7-ray light source, so the photosensitive member is placed perpendicular to the scanning electrode group 3. By moving the paper in the direction shown in FIG. At this time, the light in the short wavelength range generated by the discharge is irradiated in a spot shape through the light guide path 21 provided on the face plate 8, so that a high-resolution image can be obtained.

[Example] FIG. 1 is a plan view showing an example of a discharge light emitting device according to the present invention, and FIG. 2 is a partial sectional view thereof.

In FIGS. 1 and 2, the scanning electrode group 3 on the substrate 2"
are arranged parallel to each other in a band-like manner, and the signal electrode group 5 is arranged diagonally across the scanning electrode group 3 with an insulating layer 4 interposed therebetween. With such an electrode configuration, the distance between each intersection becomes wider, and discharge control becomes easier. Copper, chromium, or the like is used for the scanning electrode group 3 and the signal electrode group 5, and both can be formed by vapor deposition using resistance heating or electron beam heating.

Incidentally, reference numeral 13 in FIG. 1 is a defined core pole group which is electrically floating in order to prevent crosstalk due to expansion of the discharge area, and is formed simultaneously with the signal electrode group 5 in the same process. The insulating layer 4 is made of glass or 5i02kJ, and can be formed by vapor deposition using electron beam heating. A dielectric protective layer 6 is further uniformly formed on the surface of the signal electrode group 5. This protective layer is for preventing damage to the electrodes due to discharge, and its material and formation method are the same as those for the insulating bar 4. In addition, this protective layer should be made of magnesium oxide or other material with a high secondary electron emission coefficient. A? If a tt body is used, this can be achieved by lowering the discharge starting voltage.

A face plate 8 is arranged on the front surface of the substrate 2 at a predetermined interval, and the outer peripheries of the substrate 2 and the face plate 8 are sealed with a seal member 9. An opening [O] is formed at one end of the face plate 8 and is connected to a gas introduction path 12 having a mercury reservoir 11. Also,
A light guide path 21 is provided on the face plate 8 at a position corresponding to each intersection of the scanning electrode group 3 and the signal electrode group 4. FIG. 3 shows a plan view of the face plate.
Transmission iI for light in the ultraviolet 1 range such as aF2)! A rod made of a material 4 having a good S ratio and processed into a cylindrical shape is fixed with heat for a predetermined period by a light shielding member 22, and is further formed integrally with the face plate 8. As the light shielding member 22, it is preferable to use a colored polymer compound or glass, and in particular, it is preferable to use a low melting point crystallized glass or the like from the viewpoint of gas sealing properties.As for the face plate 8, a glass or the like is used. Also,
The substrate 2 is desirably made of the same material as the face plate 8 in order to have the same coefficient of expansion.Furthermore, the seal member 9 is made of low melting point glass.

A cell formed by the face plate 8 and the substrate 2''
A discharge gas 7 is sealed in eight discharge spaces. As this discharge gas, a mixture of mercury and an inert gas such as helium or argon is used. These mercury-containing discharge gases are suitable for obtaining light in a relatively short wavelength region such as ultraviolet rays, but since mercury has a low vapor pressure at room temperature, it is necessary to heat the cell container with an appropriate heating means. There is. Reference numeral 1 in the figure shows an example of such a heating means, and in order to maintain a uniform temperature throughout the cell container, it is desirable to use a planar heating element such as a ceramic heater.

In the E configuration, perpendicular lines passing through each intersection of the scanning electrode group 3 and the signal electrode group 5 and perpendicular to the scanning electrode group 3 are arranged at equal intervals of 8 to 1 B/m, thereby achieving one equivalent. It can be used as a high-resolution array light source. The scanning electrode group 3 and the signal electrode group 5 of the thus obtained discharge light emitting device have a predetermined frequency of 100 K) per pole.
z, by sequentially applying a rectangular wave voltage with an interelectrode voltage of about 300 V at 1/8 duty, and moving the photosensitive paper surface described above in a direction approximately perpendicular to the scanning J4i group 3, different wavelengths can be detected. Light containing ultraviolet rays can be sequentially irradiated onto the paper surface.

FIG. 4 shows an example of image formation using the above discharge light emitting device. FIG. In Figure 4, 2
0 is the discharge light emitting element described above, and scanning voltage applying means 1
4 and a predetermined signal voltage applied from the signal voltage applying means 15, each row sequentially emits light. The signal '-[pressure applying means 5 includes signal delay means (not shown) for correcting the position zl of each scanning electrode n3. 1
B is a photosensitive member, for example, diazo photosensitive paper or the like may be used for the purpose of checking the operation of the discharge light emitting device 20. The photosensitive member 1B is exposed on the face plate surface of the discharge light emitting device 20 as shown in the figure. It is configured to slide in the direction of the arrow in the contact state jE.

In the configuration shown in L, when a signal corresponding to image information is applied to the discharge light emitting element 20 from the scanning voltage application means 14 and the signal voltage application stage 15, and the photosensitive member 16 is moved in the direction of the arrow in FIG. The light in the ultraviolet region guided to the optical path 21 is irradiated in a spot shape, making it possible to obtain a good image with high resolution. In this case, since the light is directly irradiated from the face plate onto the surface of the photosensitive member, it is also possible to use light in the vacuum ultraviolet range without attenuating it in the air.

In addition, in the embodiment described in ``-'', an imaging effect can be obtained by using crown glass or the like for the light guide path 21 and achieving a hj: refractive index distribution in the radial direction by ion exchange. You can get high resolution images.

[Effects of the Invention] As explained above, according to the present invention, resolving power is high;
It is possible to use a discharge light-emitting element with easy discharge control, and if it is used as a writing light source for an image forming method that uses a photosensitive member that is exposed to light in a plurality of different wavelength ranges and each develops a different color, it is possible to use a color hard disk. Copies can be easily obtained. Also.

Since no lens shade is used as an imaging element, the apparatus can be made smaller.

[Brief explanation of drawings]

FIG. 1 is an 11th view of an embodiment of the discharge light emitting device according to the present invention, FIG. 2 is a sectional view thereof, FIG. It is. 2: No. 5 (plate, 3: scanning electrode group, 4: insulating layer, 5: signal electrode group, 6: +'J electrical protection layer, 7: discharge gas, 14:
Scanning voltage applying means, 15: Signal voltage applying means, 20: Discharge light emitting element. 21: Light guide path.

Claims (1)

[Claims] 1) A discharge gas is sealed in a cell container composed of a plurality of insulating members, and a first electrode group and a second electrode group intersect with each other.
In the discharge light emitting device, a discharge light emitting element is provided with electrode groups, and discharge is caused at selected intersections of the first and second electrode groups. The second electrode group is arranged to cross diagonally with respect to the first electrode group so that perpendicular lines perpendicular to the first electrode group are lined up at equal intervals in the horizontal direction, and A discharge light emitting device characterized in that a part thereof is provided with a group of light guide paths corresponding to each intersection of both electrode groups.