KR20020018494A - Optical Apparatus of Rear Projector - Google Patents

Abstract

PURPOSE: A rear projection optical system is provided to improve the setting structure of a projection mirror that reflects a beam projected by a projection optical system to reduce the thickness of the entire system. CONSTITUTION: A rear projection optical system includes a screen(50), a projection optical system(60) whose optical axis is set in parallel with the screen, and a small-sized mirror(75) that is inclined at a predetermined angle to the optical axis and perpendicular to the horizontal plane to reflect a beam. The optical system further has a medium-sized mirror(73) that is inclined at a predetermined angle at the bottom of the screen and receives the beam reflected from the small-sized mirror to project the beam upward, and a large-sized mirror(71) that is inclined at a predetermined angle at the upper part of the screen, opposite to the medium-sized mirror, and reflects the beam inputted from the medium-sized mirror on the screen.

Description

Rear Projection Optics {Optical Apparatus of Rear Projector}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a projection for greatly enlarging a small image image onto a screen through a projection system, and in particular, provided between the projection system and the screen to maintain a projection distance (distance from the projection lens of the projection system to the screen). The present invention relates to a rear projection optical system for reducing the thickness of a system by improving the installation angles of a plurality of reflecting mirrors.

In general, a projection system is composed of a light transmissive screen, a projection optical system, and a projection mirror that reflects the projection light projected from the projection optical system toward the screen, and the projection mirror has a projection distance at different numbers and installation angles. The size of the projection mirror and its installation structure serve as important factors as the size determining element of the whole system.

The liquid crystal device used in the projection optical system includes a liquid crystal display and a liquid crystal on silicon, and the transmission type refers to a type in which ambient light or fluorescent light is incident from the rear surface to display an image. It refers to the type that reflects the light incident on the front of the panel to the reflector attached to the back of the panel, and the projection system is a front type to install an image with one color liquid crystal element, and 3 There is a rear type (rear type) in which the monochromatic liquid crystal device of the intestine is installed to implement an image.

The conventional projection system of S-VISION of the United States of America is a rear type, as shown in Figs. 1 and 2, a projection optical system 3 installed so that the optical axis is perpendicular to the surface of the screen 1, A small mirror 5 positioned opposite to the projection optical system 3 and inclined at a predetermined angle at a lower end of the screen 1, and an upper end of the screen 1 facing the small mirror 5; A middle mirror 7 installed to be inclined at a position rotated counterclockwise about the intersection with the screen 1, and a predetermined angle with the screen 1 opposite to the screen 1. It is installed to be inclined and consists of a mirror (9) for receiving the light reflected through the mirror (7) to reflect to the screen (1).

In the conventional projection system configured as described above, a light beam corresponding to an image of a color formed in a liquid crystal panel (not shown) is projected through a projection lens (not shown) of the projection optical system 3, and the projected image is displayed on the screen 1. Reflected upward through the small mirror 5 installed at a predetermined angle at the lower end of the screen, and is projected onto the middle mirror 7 installed at the top of the screen 1, and the image projected on the heavy mirror 7 is again predetermined. It is reflected at the angle of the projected on the mirror (9), the image projected on the mirror (9) is projected on the screen (1) again to reflect the image.

However, in the conventional rear projection optical system configured as described above, the optical structure is installed such that the optical axis of the projection optical system 3 is perpendicular to the surface of the screen 1, and the small mirror 5 is clockwise at the bottom of the screen 1. It is installed to be inclined at a predetermined angle along the direction, a heavy mirror (7) is installed at an upper end of the screen (1) inclined at a predetermined angle along the counterclockwise direction, the anti-mirror (9) is the screen (1) Since the projection distance is long as it is installed to be inclined at a predetermined angle on the rear side of the), there is a problem that the thickness (d) of the entire system is large.

For reference, according to the projection optical system of S-VISION, the projection distance is 1000 mm, and the thickness d is 14 ".

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and has a rear projection optical system that improves the installation structure of the projection mirror that reflects the projection light projected by the projection optical system toward the screen, thereby reducing the thickness of the entire system and making the product slimmer. To provide.

The rear projection optical system according to the present invention configured as described above comprises a screen, a projection optical system having an optical axis parallel to the screen surface, a small mirror installed at a predetermined angle with respect to the optical axis and being upright with respect to a horizontal plane to reflect light; A middle mirror installed at an inclined angle at a lower end of the screen to receive the light reflected from the small mirror and projecting the light upward; an inclined at a predetermined angle at an upper end of the screen to face the heavy mirror; Characterized in that the mirror configured to reflect the light incident from the heavy mirror onto the screen.

1 is a side configuration diagram showing the structure of an optical system of a conventional projection system,

2 is a three-dimensional block diagram showing the structure of an optical system of a conventional projection system,

3 is a longitudinal sectional view showing a configuration of a projection system according to the present invention;

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a front view showing the configuration of a projection system according to the present invention;

6 is a block diagram showing the configuration of a projection optical system of the projection system applied to the present invention,

7 is a three-dimensional block diagram showing the configuration of an optical system of the projection system according to the present invention.

<Description of the reference numerals for the main parts of the drawings>

50: screen 60: projection optical system

71: heavy mirror 73: heavy mirror

75: small mirror D: product thickness

Hereinafter, with reference to the accompanying drawings 3 to 7 will be described in more detail the configuration and operation of the present invention.

As shown in the figure, the projection system according to the present invention includes a front case 41, a rear case 42, and an outer case 40 composed of a base plate 43. A screen 50 is provided at the front side, and a projection optical system 60 and a projection mirror for reflecting the projection light toward the screen 50 are disposed therein.

The projection optical system 60 is provided with an optical axis parallel to the surface of the screen 50, and the projection mirror is composed of large, medium, and small mirrors (71, 73, 75).

The small mirror 75 has a predetermined angle with respect to the optical axis of the image light projected through the projection optical system 60 and is installed to be perpendicular to the surface of the base plate 43 in a direction perpendicular to the screen 50. It is installed to reflect the light, the heavy mirror 73 is predetermined at the lower end of the screen 50 to face the small mirror 75 to receive the light reflected from the small mirror 75 and to project upwards. It is installed to be inclined at an angle of, the anti-mirror 71 of the screen 50 to face the heavy mirror 73 so as to reflect the light incident from the heavy mirror 73 onto the screen 50 It is installed to be inclined at a predetermined angle along the direction in which the heavy mirror 73 is installed at the top.

The installation angle α ° of the small mirror 75 is installed to be inclined at 45 ° with respect to the optical axis of the light projected through the projection optical system 60, and the anti-mirror 71 and the heavy mirror 73 are The inclination angles are installed to be equal to each other.

The angles of the large, medium, and small mirrors (71, 73, 75) are maintained by the frame (80) and the first, second, third brackets (91, 93, 95) provided on both sides of the base plate (43). And fixed.

The projection optical system 60 blocks the lamp 61 irradiating white light and wavelengths unnecessary for screen formation among the white light irradiated from the lamp 61, ie, ultraviolet rays of 380 mm or less, infrared rays of 780 mm or more, and the like. And a hot mirror 62 for passing visible light of 380 to 780 mm, a first mirror 63 for reflecting light projected through the hot mirror 62 in a predetermined direction, and the first mirror 63. A fly's eye lens 64 for converting the light reflected through the parallel light into a parallel light, a condensing lens 65 for collecting the light converted through the fly's eye lens 64, and a projection through the condensing lens 65 The second and third mirrors 66a and 66b for converting and reflecting the light to a predetermined angle and the light reflected through the third mirror 66b are respectively R (red) / G (green) / B ( Blue) is separated to project to the liquid crystal elements (67a, 67b, 67c) and then the light is adjusted through the R / G / B liquid crystal elements (67a, 67b, 67c) color A color beam splitting / compositing unit for recombining light colored with a color beam corresponding to the image, and a projection lens 69 for projecting the synthesized light synthesized through the color beam splitting / compositor 68 onto the screen 50; Is made of.

The color beam splitter / compositor 68 is provided with first and second dichroic mirrors 68a and 68b so that the G light of the light incident through the second mirror 66a is the first dichroic mirror ( R light is transmitted through the second dichroic mirror 68b through the second dichroic mirror 68a and is incident on the G liquid crystal element 67b, and is reflected through the first dichroic mirror 68a. Incident to the R liquid crystal element 67a, and the B light that has not passed through the second dichroic mirror 68b is reflected and separated into the B liquid crystal element 67a, thereby causing the respective R / G / B liquid crystal elements ( 67a, 67b, and 67c, which are controlled by light transmission to be colored and reflected by the color beam corresponding to the color image, and the reflected light is configured to pass through the projection lens 69 after being synthesized by the photosynthetic means (not shown). do.

The R / G / B liquid crystal elements 67a, 67b, and 67c have a reflection type, and the incident light is controlled by the R / G / B liquid crystal elements 67a, 67b, and 67c. It is configured to be reflected.

The lower end of the frame 80 is fixed to both sides of the base plate 43 by fixing screws (not shown), and the upper end thereof is inclined at a predetermined angle to form an installation angle of the anti-mirror 71. It is formed, the first bracket 91 is provided on the upper surface of the inclined frame 80 to fix the anti-mirror 71 inclined at a predetermined angle.

The second bracket 93 is bent at a predetermined angle to maintain the installation angle of the heavy mirror 73 so that one side of the second bracket 93 is in contact with the bottom surface of the heavy mirror 73 and the other side of the base plate ( 43) is fixed to the upper surface by a separate fastening screw.

The third bracket 95 is bent to be perpendicular to the surface of the base plate 43 so that one side is fixed to the upper surface of the base plate 43, the other side is the rear surface of the small mirror 75 Joined in contact.

In the above, the large, medium and small mirrors (71, 73, 75) is configured to be coupled to the first, second, third brackets (91, 93, 95) by a separate holder member (not shown).

Next, the operation and effects of the rear projection optical system according to the present invention configured as described above will be described.

First, when white light including R / G / B 3 wavelengths is emitted from the lamp 61 of the projection optical system 60 at the same ratio, the emitted light is visible light (380 to 780 mm) through the hot mirror 62. ), Unnecessary wavelengths such as ultraviolet rays of 380 mm or less and infrared rays of 780 mm or more are blocked, and the light passing through the hot mirror 62 is reflected through the first mirror 63 to fly. It passes through the eye lens 64.

The light converted into parallel light through the fly's eye lens 64 is collected again by the condenser lens 65, and the collected light is reflected through the second and third mirrors 66a and 66b to be used as the first dike. It enters into the mirror 68a.

Among the light incident to the first dichroic mirror 68a, G light passes through the first dichroic mirror 68a and enters the G liquid crystal element 67b, and the first dichroic mirror 68a. The R / B light reflected through the plane is incident on the second dichroic mirror 68b, and the B light of the R / B light incident on the second dichroic mirror 68b is the second dike. The light is reflected through the lower mirror 68b and incident on the B liquid crystal element 67c, and the R light passes through the surface of the second dichroic mirror 68b and enters the R liquid crystal element 67a.

As described above, the R / G / B light incident on each of the R / G / B liquid crystal elements 67a, 67b, and 67c is light-transmitted through the R / G / B liquid crystal elements 67a, 67b, and 67c to be colored. After being colored with a color beam corresponding to an image, it is reflected and recombined again through a photosynthesis means (not shown), and then is magnified and projected through the projection lens 69, and the light projected through the projection lens 69 is projected to an optical axis. The incident light is incident on the small mirror 75 which is inclined at a predetermined angle with respect to the predetermined mirror, and is reflected at a predetermined angle. The reflected light is incident on the heavy mirror 73 and then reflected upwards. After the projection on the mirror 71 is reflected at a predetermined angle is projected on the screen 50 to reflect the image.

In the rear projection optical system projected as described above, the small mirror 75 is installed to be inclined at a predetermined angle (45 °) with respect to the optical axis of the light projected through the projection lens 69 and the small mirror 75 is rotated. The middle mirror 73 for receiving the light reflected through the reflection to the upper side is installed to be inclined at a predetermined angle at the bottom of the screen 50, the screen 50 receives the light reflected through the heavy mirror (73) By installing the anti-mirror 71 projecting on the upper surface of the screen 50 to maintain the same angle as the inclined angle of the heavy mirror 73, the projection distance can be shortened, thereby The thickness D is reduced to make the product slimmer.

For reference, the projection distance is 630 mm, the thickness (D) is 12 ″, compared with the conventional S-VISION company, it can be seen that the projection distance and the system thickness is significantly reduced.

As described above, the rear projection optical system according to the present invention installs the optical axis of the light projected from the projection lens in parallel with the surface of the screen and at the same time installs the small mirror inclined at a predetermined angle with respect to the optical axis. Projection distance is installed so as to be upright with respect to, the heavy mirror is installed at an angle to the bottom of the screen inclined at a predetermined angle, the anti-mirror is installed at a predetermined angle on the top of the screen in parallel with the installation angle of the heavy mirror By reducing the thickness of the system, and thus reducing the thickness of the overall system to achieve a slimmer product.

Claims (3)

Screen; A projection optical system provided with an optical axis parallel to the screen surface; A small mirror installed at an angle with respect to the optical axis and installed upright with respect to a horizontal plane to reflect light; A heavy mirror installed at an inclined angle at a lower end of the screen to receive light reflected from the small mirror and project the light toward the upper side; The rear projection optical system is configured to be inclined at a predetermined angle on the top of the screen so as to face the heavy mirror to reflect the light incident from the heavy mirror onto the screen. The method of claim 1, And the small mirror is installed at 45 degrees with respect to the optical axis. The method of claim 1, The rearview mirror optical system, characterized in that the inclined angle of the heavy mirror and the mirror.