KR960004410Y1 - Optical projector - Google Patents

Abstract

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Description

Optical projection

1 is a conventional optical projection apparatus.

2 is an optical projection apparatus of the present invention.

* Explanation of symbols for main parts of the drawings

100: red cathode ray tube 200: green cathode ray tube

300: blue cathode ray tube 400, 401, 402: projection lens

500, 501, 502: refrigerant coupler 600, 601, 602: glass fiber optical plate

The present invention relates to an optical projection apparatus, and in particular, since the cathode ray tube projecting red and blue images is installed at an angle, the installation space of the cathode ray tube must be increased, and the refrigerant coupling device combining the cathode ray tube and the projection lens. It is an object of the present invention to provide an optical projection apparatus that can solve the problem of manufacturing cost increase due to high precision in manufacturing.

Cathode ray tube (CRT) projection apparatus (or cathode ray tube projection TV), which is currently in practical use, has a front projection method and a rear projection method, and is generally composed of an optical device of a 3 tube 3 lens method. .

FIG. 1 is an in-line conventional cathode ray tube optical projection apparatus, which is separated at an angle of 120 degrees, is installed at an angle with respect to the center cathode ray tube, and realizes a red, green, and blue monochrome image, respectively. Cathode ray tube 20, blue cathode ray tube 30, and projection lens 40 for enlarging and projecting images output from the cathode ray tubes on screen 50, and cathode ray tubes of red, green, and blue with the projection lenses. It was composed of a refrigerant coupling unit 50 for connecting the refrigerant in a state filled.

In the conventional cathode ray tube optical projection apparatus configured as described above, the monochrome image implemented in the cathode ray tubes of red, green, and blue are respectively enlarged while passing through the projection lens and projected onto the screen, as shown in FIG.

Accordingly, a red, green, and blue image is synthesized on the screen to realize a color image, and the image can be observed from the front or rear side according to the image implementation method.

However, in the conventional in-line three-tube three-lens cathode ray tube projection apparatus, since three cathode ray tubes are separated as shown in FIG. 1, a convergence angle θ is generated.

Therefore, in order to enlarge and image the single color from the red and blue cathode ray tubes projecting an image on the screen, the angle between each cathode ray tube and the projection lens must be corrected by an angle of β.

This correction angle β is usually called the Scheimphlug angle, which depends on the convergence angle β and acts as a significant influence on the system configuration.

Projection devices currently commercialized generally have the configuration as shown in FIG. 1 and implement the Scheimphlug angle by means of a refrigerant coupling device combining a cathode ray and a projection lens.

Therefore, in the conventional cathode ray tube projection optical device, the refrigerant coupling device has to be manufactured very precisely in order to realize an accurate Scheimphlug angle. Therefore, the manufacturing cost increases and a projection optical device requiring high precision is required. The technical problem that it is difficult to implement, and because the blue cathode ray tube of the red cathode ray tube is opened at an angle corresponding to the sum of the convergence angle and the Scheimphlug angle with respect to the center green cathode ray tube, more spaces than necessary are occupied by the cathode rays. there was.

The object of the present invention is to provide an optical projection device that corrects the Scheimphlug angle by attaching a glass fiber optical plate to the front surface of the cathode ray tube by arranging the cathode ray tubes of red, green, and blue horizontally to solve the above problems. It is done.

The object of the present invention is to place red, green and blue cathode ray tubes that project images of red, green and blue in parallel and Scheimphlug angles in front of the red, green and blue cathode ray tubes and perpendicular to the projection lens optical axis. The glass fiber optical plate is attached in the shape of a wedge to form a glass fiber material, and the glass fiber optical plate is formed by attaching the green cathode ray tube in the form of a parallel plate, and the cathode ray tube, the glass fiber optical plate, and the projection lens are combined and supported to project. It can be achieved by consisting of a refrigerant coupling portion for cooling the heat generated in the tube.

2 is a red, green, and blue cathode ray tubes 100, 200, and 300 arranged in parallel with the inventive optical projection apparatus, and a green image which magnifies and transmits an image transmitted and placed on a line with the green cathode ray tube 200. A projection lens 401, a red projection lens 400 and a blue projection lens 402 for enlarging an image transmitted separately by a convergence angle θ to the green projection lens, and the red, green, and blue projection lenses 400,401,402 Red, green, and blue glass fiber coupling unit (500, 501, 502) for coupling with the red, green, blue cathode ray tube (100, 200, 300), respectively, and red, green, blue glass fiber to transfer the image transmitted from the cathode ray tube inside the refrigerant coupling unit without loss of light amount The optical plates 600, 601 and 602, and the red and blue glass fiber optical plates 600 and 602 are used to correct the Scheimphlug angle and β of the red and blue cathode ray tubes 100 and 300 and the red and blue transparent lenses 400 and 402. Has a wedge-shaped structure, the rust A glass fiber optical plate 601 has a structure of a parallel-plate behavior.

The optical projection apparatus of the present invention constructed as described above will be described in detail with reference to FIG. 2.

First, as a method for correcting the Scheimphlug angle, a wedge-shaped glass-fiber optical plate manufactured by attaching one side to the cathode ray tube surface and the other side to achieve the Scheimphlug angle with respect to the surface perpendicular to the projection lens optical axis was installed.

The glass fiber optical plate is an optical component capable of transferring a certain image from one side to the other without loss of light.

Therefore, the image formed on the surface of the cathode ray tube is transferred to the other side of the glass fiber optic plate without energy loss, and the image formed on this surface is enlarged through the projection lens to be projected onto the screen to display the image.

On the other hand, a glass fiber optic plate parallel to both sides is attached to the green cathode ray tube surface on the central axis, which is installed to match the other cathode ray tube lens assembly with TCL.

In general, the cathode ray tube projection optical device is coupled between the cathode ray tube and the projection lens in a state filled with a refrigerant to improve cooling and transmittance of the cathode ray tube.

In the existing method of FIG. 1, such a refrigerant coupling device must be designed and manufactured considering the convergence angle and the Scheimphlug angle at the same time, and in particular, a very precise design must be made mechanically to implement the Scheimphlug angle.

As described in detail above, since the optical projection apparatus of the present invention implements the Scheimphlug angle by the glass fiber optical plate, it is not necessary to consider the Scheimphlug angle in the refrigerant coupling device, and design the refrigerant coupling device by arranging three cathode ray tubes in parallel. It is possible to design by considering only the time convergence angle, and the space occupied by the cathode ray tube becomes small, so that it is easy to install other components such as a speaker or a circuit board, thereby miniaturizing the device set.

Claims (2)

(Correction) Red, green and blue cathode ray tubes arranged in parallel to project red, green and blue images respectively, and attached to the red, green and blue cathode ray tubes to project images from the cathode ray tubes without loss of light. A glass fiber optical plate that is refracted and transmitted to project the screen through a projection lens, and the cathode ray tube, the glass fiber optical plate, and the projection lens are combined and supported, and heat generated from the cathode ray tube using a coolant therein. Optical projection device characterized in that consisting of a refrigerant coupling portion for cooling. (Correction) The glass fiber optical plate according to claim 1, wherein the glass fiber optical plate is attached to the front surface of the red and blue cathode ray tubes in a wedge shape so as to correct the Scheimphlug angle with respect to the plane perpendicular to the projection lens optical axis, and the parallel plate to the green projection tube. Optical projection apparatus, characterized in that made of a green glass fiber optical plate that is attached in the form and transmits the light amount without loss.