KR100190553B1 - Color display-board using liquid crystal - Google Patents

Abstract

[0001] The present invention relates to a liquid crystal light emitting type color electric signboard, which is a light source for each pixel side 10 installed on the front side of an electric signboard, and is a light source for red, green, blue and white The fluorescent lamps R, G, B, and W are arranged in a transverse direction between a plurality of light shielding walls 1, a light pipe 20 having a double pipe structure is connected to each of the pixels 10 in front, A shielding film 5 is formed on the outer tube a of the optical transmission tube 20 at positions corresponding to the respective shielding walls 1 and liquid crystals are filled between the respective shielding films 5, An electrode 3 is formed on an outer circumferential surface and an inner circumferential surface of the liquid crystal tube 2 and an inner tube b of the optical transmission tube 20 is formed with three conical grooves, The cylindrical lens 4 is inserted side by side so that the electric field is selectively applied to the electrode 3 formed on the liquid crystal tube 2 according to the R, G, B, and W signals To a liquid crystal light-transmissive color electric signboard configured to emit light of a fluorescent lamp of a desired color toward the pixel (10) side by switching the liquid crystal tube to a transparent state.

Description

Liquid-crystal-type color display board

As shown in FIG. 1, a conventional color electric sign board has a plurality of pixels 10 formed on the front face of a light bulb, and each of the red, green, blue and white A dot matrix type in which four fluorescent elements (R, G, B and W) emitting light is used together has been used.

However, in such a conventional color electric sign board, since four independent fluorescent elements are formed in block form in each pixel, in order to manufacture such an electric sign board, a large number of independent independent fluorescent elements are required. Therefore, the manufacturing cost was considerably high.

Further, in the conventional color electric sign board, in order to emit light of a desired color from one pixel in which fluorescent elements of R, G, B and W colors are integrated, only the fluorescent elements of the required color have to be individually turned on . However, from a general point of view, a light emitting element such as a fluorescent lamp or the like is coated with a fluorescent material on its inner surface or is filled with various fluorescent lamps. When the lamp is turned on for a long time, it is advantageous in terms of power consumption. However, when the lamp is turned on again in a turned-off state, a large amount of power loss is caused. have.

Therefore, in a conventional dot matrix type color electronic billboard, in order to obtain a desired color among the hues of R, G, B, or W from each pixel, the required fluorescent element among the four fluorescent elements maintains the on state, As the fluorescent elements of different colors not required are to be in the unlit state, the independent and vast number of fluorescent elements are repeatedly turned on and off according to the R, G, B and W signals applied to the electric panel, Respectively.

Therefore, although the conventional color electronic signboard has the advantage of displaying a still image for a long time, it is disadvantageous because a power consumption to be used for displaying a moving image is extremely high.

In general, a liquid crystal is a liquid, and optically displays a crystal-like property, and has a property that transparency to light changes according to an electric or magnetic field applied to the liquid crystal, There is a property that light can not pass through unless light passes through and electric field is applied.

The applicant of the present invention has developed the present invention in consideration of the fact that liquid crystal has the above-mentioned properties. As in the conventional color electric sign board, the fluorescent display device of each of R, G, B and W colors G, B and W color fluorescent lamps are arranged with a light shielding wall interposed therebetween for each pixel layer laid in one lateral direction out of the pixels formed on the front side of the electric sign board in the present invention Each of the fluorescent lamps formed in the one pixel layer is configured to be used as a common light source for all the pixels laid laterally in the one pixel layer, and light emitted from each of the fluorescent lamps A liquid crystal tube filled with a liquid crystal is allowed to pass therethrough so that the electric field is selectively applied to each of the liquid crystal tubes in accordance with the R, G, B, and W signals, Only a tube is converted into a transparent state so that the light of a desired color from the corresponding fluorescent lamp can be emitted to the pixel side through the tube, thereby reducing the manufacturing cost and the operating cost of the apparatus. .

1 is a front view of a conventional dot matrix type color electric sign board.

FIG. 2A is a side cross-sectional view of the liquid crystal light transmission type color electric sign board of the present invention. FIG.

FIG. 2B is an exploded view showing a coupling structure of the optical transmission tube 20 in FIG. 2A. FIG.

3 is a cross-sectional view of a liquid crystal light-transmitting color electric signboard of the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

1. Shading wall 2. Liquid crystal tube

3. Electrode 4. Cylindrical lens

5. Breaker 10. Pixel

20. Optical transmission tube R. Red fluorescent lamp

G. Green fluorescent lamp B. Blue fluorescent lamp

W. White Fluorescent Lamp

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

2A is an exploded view showing the structure of the light transmission tube 20 in FIG. 2A, FIG. 3 is a sectional view of the liquid crystal light transmission type color electric sign board of the present invention, and FIG. And shows a layout of fluorescent lamps arranged for each pixel layer in a cross-sectional view.

As shown in FIG. 2A, a plurality of pixels 10 are provided in a multilayer structure in front of the main body of the liquid crystal transflective color electric signboard according to the present invention. A light transmission tube 20 having a double tube structure of an inner tube b and an outer tube a is formed and a plurality of light shielding walls 1 are formed on the upper and lower sides of the optical transmission tube 20, Green, and blue fluorescent lamps R, G, and B are disposed between the respective light-shielding walls 1 at predetermined intervals so that the ends of the light-transmitting tube 20 and the light- 1, a white fluorescent lamp W is disposed between the light shielding wall and the light shielding wall at the first end.

Here, the layout of each of the fluorescent lamps R, G, B, and W for each pixel layer can be more clearly understood with reference to FIG. 3, a red fluorescent lamp R of the fluorescent lamps R, G, B, and W is disposed between the first and second light-shielding walls of the plurality of light-shielding walls 1, And the green fluorescent lamp (G) is disposed transversely between the second light shielding wall and the third light shielding wall, and the blue fluorescent lamp (B) is disposed between the third light shielding wall and the fourth light shielding wall And are arranged in the transverse direction between the light shielding walls. Although not shown here, the white fluorescent lamp W is arranged in the lateral direction in the space formed between the light shielding wall at the first end of the light shielding wall 1 and the end of the light transmission tube 20 .

2B, the liquid crystal light emitting type color electric sign board of the present invention constitutes a pixel 10 made of a lens at the front side of the light transmission tube 20, and the outer tube (not shown) of the light transmission tube 20 a shielding film 5 is formed at the same position as the installation position of the light shielding walls 1 and then a liquid crystal is filled between each of the shielding films 5 to form a plurality of liquid crystal tubes 2 . An electrode 3 for applying an electric field to the liquid crystal in the liquid crystal tube 2 is laid on the inner and outer circumferential surfaces of the respective liquid crystal tubes 2 And the like). 2A, each of the liquid crystal tubes 2 is formed corresponding to each of the fluorescent lamps R, G, B and W, and the electrodes 3 formed on the outer and inner peripheral surfaces thereof When the electric field is applied, the liquid crystal tube 2 becomes transparent.

As shown in the drawing, three cylindrical lenses 4 having the same length as the spacing of the light-shielding walls 1 are inserted in the inner tube b of the optical transmission tube 20 in parallel. Here, each of the cylindrical lenses 4 is formed with a conical groove toward the center thereof, and the inner wall of the conical groove is subjected to a sanding treatment. Therefore, when light is incident on the cylindrical lens 4, the light is scattered in the conical groove and is emitted to the pixel 10.

Hereinafter, the operation and effect of the liquid crystal light transmission type color electronic signboard of the present invention will be described with reference to FIG. 2A.

Although not shown, power lines for supplying current are connected to the electrodes 3 attached to the inner and outer circumferential surfaces of the liquid crystal tubes 2, respectively.

In the liquid crystal transflective color electric signboard according to the present invention, unlike the conventional color electric signboard, the fluorescent lamps (R, G, B, and W) are always kept lit. In this state, in accordance with the R, G, B, and W signals supplied from the separate controllers, the liquid crystal tubes 2 corresponding to the respective fluorescent lamps R, G, B, When an electric field is selectively applied to an electrode attached to a tube through a power line, the liquid crystal filled in the liquid crystal tube to which the electric field is applied is converted into a transparent state. Then, while the electric field is continuously applied, the light of the fluorescent lamp corresponding to the liquid crystal tube converted into the transparent state passes through the transparent liquid crystal tube. Subsequently, the light of the required color transmitted through the liquid crystal tube passes through the cylindrical lens 4 inserted in the inner tube b of the optical transmission tube 20. At this time, the light from the fluorescent lamp of the required color passing through the cylindrical lens 4 is scattered and dispersed while passing through the cylindrical lens 4, and finally, the light is transmitted to the pixel 10.

For example, when an R signal is applied from among the R, G, B, and W signals, an electrode 3 formed in a liquid crystal tube corresponding to a red fluorescent lamp R among the liquid crystal tubes 2 The liquid crystal tube is turned to be transparent and ultimately a red light is transmitted to the pixel 10. When a W signal is applied to the pixel 10, An electric field is applied to the electrodes formed at both ends of the liquid crystal tube which is in contact with the white fluorescent lamp W so that the liquid crystal tube is converted into a transparent state and ultimately a white light is transmitted to the pixel 10 .

In order to convert the liquid crystal tube 2 into a transparent state, an electric field applied to the electrode 3 formed on the inner and outer circumferential surfaces of the liquid crystal tube may be a very small current.

In the present invention, the fluorescent lamps R, G, B, and W are always in a lighted state. However, in a state where the fluorescent lamps are once turned on due to the characteristics of the fluorescent lamps, Therefore, the power consumption is very small, which causes no problem in the operation cost.

Therefore, according to the liquid crystal transflective color electric sign board of the present invention, the fluorescent elements (R, G, B, and W) of four colors configured for each pixel are separately The fluorescent lamps R, G, B, and W of four colors are formed in common for each pixel layer, and then the fluorescent lamps are kept in a lighted state, G, B and W signals so that only the required liquid crystal tube is made transparent so that only the light of the corresponding fluorescent lamp is transmitted to the pixels 10 through the liquid crystal tube Therefore, according to the liquid crystal transflective color display board of the present invention, the power used when displaying a moving image can be extremely reduced, and the operation cost incurred in using the apparatus can be reduced. On the other hand, (R, G, B, and W) is used as a common light source for each pixel layer, it is possible to lower the equipment cost incurred in manufacturing the device, thereby greatly reducing the cost incurred in manufacturing and operating the device There is an economical effect.

Although the optical transmission tube 20 is formed in a circular double tube structure in the drawings of the present invention, the optical transmission tube 20 may have a rectangular double tube structure. In this case, the cylindrical lens 4 to be inserted into the inner tube b of the optical transmission tube 20 should also have a rectangular shape.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color electronic signboard used for outdoor advertising, a color electronic signboard which is installed in a station or a terminal, and which can be commonly applied to a small color electronic signboard, To a liquid crystal light-transmitting color display board constituted by using light transmittance of a liquid crystal so as to reduce various costs incurred in a liquid crystal display.

Claims (1)

Green, blue and white fluorescent lamps R, G, B and W as a light source for each pixel 10 installed on the front side of the electric sign board in the lateral direction between a plurality of light shielding walls 1 (20) is connected to each of the pixels (10), and the outer tube (a) of the optical transmission tube (20) is connected to the light shielding wall 1, the liquid crystal tube 2 is formed by filling liquid crystal between the respective barrier films 5, and the inner peripheral surface of the liquid crystal tube 2, (3) for applying an electric field to the liquid crystal in the liquid crystal tube (2) are formed on the outer circumferential surface, and a conical groove formed by sanding the outer circumferential surface of the groove is formed in the inner tube (b) of the optical transmission tube The cylindrical lenses 4 are inserted side by side so that the inner circumferential surface and the outer circumferential surface of the liquid crystal tube 2, Only the required liquid crystal tube is converted into a transparent state by selectively applying an electric field according to the R, G, B, and W signals to the polarity 3 so that only the light from the fluorescent lamp that is in contact with the transparent liquid crystal tube, (10), the liquid crystal display panel comprising: